Multipoint transmission in wireless communication

ABSTRACT

Embodiments contemplate wireless transmit/receive unit (WTRU) transmissions of different types of uplink channels and/or signals in a system deployment where multiple destination points may exist. Some embodiments contemplate that a WTRU may select the destination point of a transmission on a dynamic basis. In one or more systems where destination point selection from among multiple potential destination points may be possible for a WTRU transmission, some embodiments contemplate the determination of the handling of hybrid automatic repeat request (HARQ) retransmissions and for different power headroom reporting mechanisms. Embodiments also contemplate the reduction and/or inhibition of WTRU transmissions to destination points to which the WTRU may have lost connectivity.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is the 35 U.S.C. § 371 National Stage of PatentCooperation Treaty Application No. PCT/US2012/058186, filed Sep. 30,2012, which claims the benefit of U.S. Provisional Patent ApplicationNo. 61/542,145, titled “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed Sep. 30, 2011; U.S. Provisional PatentApplication No. 61/591,789, titled “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed Jan. 27, 2012; U.S. Provisional PatentApplication No. 61/604,399, titled “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed Feb. 28, 2012; U.S. Provisional PatentApplication No. 61/616,256, “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed Mar. 27, 2012; U.S. Provisional PatentApplication No. 61/644,827, titled “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed May 9, 2012; U.S. Provisional PatentApplication No. 61/678,437, titled “MULTIPOINT TRANSMISSION IN WIRELESSCOMMUNICATIONS SYSTEM”, filed Aug. 1, 2012; the disclosures of all sevenapplications hereby incorporated by reference herein in their respectiveentirety, for all purposes.

BACKGROUND

Coordinated multipoint transmission (CoMP) for Long Term Evolution (LTE)wireless systems refers to a family of schemes involving coordinationbetween multiple geographically separated points of the network forcommunications with user equipment (UE) (or wireless transmit/receiveunit (WTRU)). In the uplink direction, CoMP can involve joint receptionof the transmitted signal at multiple reception points and/orcoordinated scheduling decisions among points to control interferenceand improve coverage.

SUMMARY

The Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used to limit the scope of the claimed subject matter.

The methods and apparatus described herein, taken alone or incombination, enable a wireless transmit/receive unit (WTRU) to transmitdifferent types of uplink channels or signals in a system deploymentwhere multiple destination points may exist. In some embodimentsdescribed herein, the methods enable a WTRU to select the destinationpoint of a transmission on a dynamic basis. In a system wheredestination point selection from among multiple potential destinationpoints may be possible for a WTRU transmission, some embodiments of thesystem and methods provide for determination of the handling of hybridautomatic repeat request (HARM) retransmissions and for new (e.g.,contemplated by embodiments) power headroom reporting mechanisms. Infurther embodiments, methods are described to reduce or inhibit WTRUtransmissions to destination points to which the WTRU has lostconnectivity. Reference signals (RS) may be enhanced by using a precyclic shift (CS) offset to compensate the peak drift due to unpairedbandwidth (BW) allocation, introducing another layer of hopping overdifferent sizes of RS′ or using method to decouple CS hopping fromselection of base sequences. Methods are also described to determine aninitial value of CS hopping and other parameters based onreinterpretation of cyclic shift field (CSF). Different transmit powercontrol (TPC) commands for aperiodic sounding reference signal (SRS),periodic SRS and physical uplink shared channel (PUSCH) are alsodescribed. Additional power control methods are described for SRS usingdecoupled TPC commands. Methods to enhance physical uplink sharedchannel (PUSCH) resource block (RB) mapping based on more dynamic PUSCHRB allocation are also disclosed. Additional methods for selection ofuplink transmission contexts (UTC) for physical uplink control channel(PUCCH) are described. Methods are also described to handle TPC commandsfor multiple UTC's or for groups of physical channels and/ortransmission types and on how to deal with subframe subsets where WTRU'smay have limited transmission possibilities, such as for example,Further enhanced inter-cell interference coordination (FeICIC).

Embodiments contemplate a wireless transmit/receive unit (WTRU), thatmay comprise a processor. The processor may be configured, at least inpart, to select at least one Uplink Transmission Context (UTC). The atleast one UTC may correspond to one or more characteristics. Theprocessor may be configured to select at least one of the one or morecharacteristics. The processor may also be configured to initiate atransmission based, at least in part, on the at least one of the one ormore characteristics.

Embodiments contemplate a wireless transmit/receive unit (WTRU) that maycomprise a processor. The processor may be configured, at least in part,to select at least one Uplink Transmission Context (UTC) that maycorrespond to a transmission type. The processor may be configured todetermine a transmit power that may correspond to the at least one UTC.The processor may also be configured to initiate a transmission that maycorrespond to the transmission type at the determined power.

Embodiments contemplate a wireless transmit/receive unit (WTRU) that maycomprise a processor, where the processor may be configured, at least inpart, to determine an initial value for cyclic shift (CS) hopping. Theprocessor may be configured to decouple the initial value for CS hoppingfrom a f_(ss) ^(PUSCH). The processor may also be configured tocorrelate the initial value for CS hopping to at least one UplinkTransmission Context (UTC).

BRIEF DESCRIPTION OF THE DRAWINGS

A more detailed understanding may be had from the following description,given by way of example in conjunction with the accompanying drawings(or figures). Figures in such drawings, like the detailed description,are examples. As such, the Figures and the detailed description are notto be considered limiting, and other equally effective examples arecontemplated, wherein:

FIG. 1A is a system diagram of an example communications system in whichone or more disclosed embodiments may be implemented;

FIG. 1B is a system diagram of an example wireless transmit/receive unit(WTRU) that may be used within the communications system illustrated inFIG. 1A;

FIG. 1C is a system diagram of an example radio access network and anexample core network that may be used within the communications systemillustrated in FIG. 1A;

FIG. 2 is a table illustrating the different downlink controlinformation (DCI) sizes resulting from different system bandwidthconfigurations consistent with embodiments;

FIG. 3 shows an example of unpaired bandwidth allocation consistent withembodiments;

FIG. 4 shows an example of correlation peak drift consistent withembodiments;

FIGS. 5 and 6 are Pcell uplink transmission contexts (UTC)configurations consistent with embodiments;

FIG. 7 is a sample table of UplinkPowerControl information elementsconsistent with embodiments;

FIG. 8 is an exemplary illustration of the cyclic shift (CS)compensation at a network consistent with embodiments; and

FIG. 9 is an example cyclic shift field consistent with embodiments.

DETAILED DESCRIPTION

A detailed description of illustrative embodiments will now be describedwith reference to the various Figures. Although this descriptionprovides a detailed example of possible implementations, it should benoted that the details are intended to be exemplary and in no way limitthe scope of the application. As used herein, the article “a” or “an”,absent further qualification or characterization, may be understood tomean “one or more” or “at least one”, for example.

FIG. 1A is a diagram of an example communications system 100 in whichone or more disclosed embodiments may be implemented. The communicationssystem 100 may be a multiple access system that provides content, suchas voice, data, video, messaging, broadcast, etc., to multiple wirelessusers. The communications system 100 may enable multiple wireless usersto access such content through the sharing of system resources,including wireless bandwidth. For example, the communications systems100 may employ one or more channel access methods, such as code divisionmultiple access (CDMA), time division multiple access (TDMA), frequencydivision multiple access (FDMA), orthogonal FDMA (OFDMA), single-carrierFDMA (SC-FDMA), and the like.

As shown in FIG. 1A, the communications system 100 may include wirelesstransmit/receive units (WTRUs) 102 a, 102 b, 102 c, 102 d, a radioaccess network (RAN) 104, a core network 106, a public switchedtelephone network (PSTN) 108, the Internet 110, and other networks 112,though it will be appreciated that the disclosed embodiments contemplateany number of WTRUs, base stations, networks, and/or network elements.Each of the WTRUs 102 a, 102 b, 102 c, 102 d may be any type of deviceconfigured to operate and/or communicate in a wireless environment. Byway of example, the WTRUs 102 a, 102 b, 102 c, 102 d may be configuredto transmit and/or receive wireless signals and may include userequipment (UE), a mobile station, a fixed or mobile subscriber unit, apager, a cellular telephone, a personal digital assistant (PDA), asmartphone, a laptop, a netbook, a personal computer, a wireless sensor,consumer electronics, and the like.

The communications systems 100 may also include a base station 114 a anda base station 114 b. Each of the base stations 114 a, 114 b may be anytype of device configured to wirelessly interface with at least one ofthe WTRUs 102 a, 102 b, 102 c, 102 d to facilitate access to one or morecommunication networks, such as the core network 106, the Internet 110,and/or the networks 112. By way of example, the base stations 114 a, 114b may be a base transceiver station (BTS), a Node-B, an eNode B, a HomeNode B, a Home eNode B, a site controller, an access point (AP), awireless router, and the like. While the base stations 114 a, 114 b areeach depicted as a single element, it will be appreciated that the basestations 114 a, 114 b may include any number of interconnected basestations and/or network elements.

The base station 114 a may be part of the RAN 104, which may alsoinclude other base stations and/or network elements (not shown), such asa base station controller (BSC), a radio network controller (RNC), relaynodes, etc. The base station 114 a and/or the base station 114 b may beconfigured to transmit and/or receive wireless signals within aparticular geographic region, which may be referred to as a cell (notshown). The cell may further be divided into cell sectors. For example,the cell associated with the base station 114 a may be divided intothree sectors. Thus, in one embodiment, the base station 114 a mayinclude three transceivers, i.e., one for each sector of the cell. Inanother embodiment, the base station 114 a may employ multiple-inputmultiple output (MIMO) technology and, therefore, may utilize multipletransceivers for each sector of the cell.

The base stations 114 a, 114 b may communicate with one or more of theWTRUs 102 a, 102 b, 102 c, 102 d over an air interface 116, which may beany suitable wireless communication link (e.g., radio frequency (RF),microwave, infrared (IR), ultraviolet (UV), visible light, etc.). Theair interface 116 may be established using any suitable radio accesstechnology (RAT).

More specifically, as noted above, the communications system 100 may bea multiple access system and may employ one or more channel accessschemes, such as CDMA, TDMA, FDMA, OFDMA, SC-FDMA, and the like. Forexample, the base station 114 a in the RAN 104 and the WTRUs 102 a, 102b, 102 c may implement a radio technology such as Universal MobileTelecommunications System (UMTS) Terrestrial Radio Access (UTRA), whichmay establish the air interface 116 using wideband CDMA (WCDMA). WCDMAmay include communication protocols such as High-Speed Packet Access(HSPA) and/or Evolved HSPA (HSPA+). HSPA may include High-Speed DownlinkPacket Access (HSDPA) and/or High-Speed Uplink Packet Access (HSUPA).

In another embodiment, the base station 114 a and the WTRUs 102 a, 102b, 102 c may implement a radio technology such as Evolved UMTSTerrestrial Radio Access (E-UTRA), which may establish the air interface116 using Long Term Evolution (LTE) and/or LTE-Advanced (LTE-A).

In other embodiments, the base station 114 a and the WTRUs 102 a, 102 b,102 c may implement radio technologies such as IEEE 802.16 (i.e.,Worldwide Interoperability for Microwave Access (WiMAX)), CDMA2000,CDMA2000 1×, CDMA2000 EV-DO, Interim Standard 2000 (IS-2000), InterimStandard 95 (IS-95), Interim Standard 856 (IS-856), Global System forMobile communications (GSM), Enhanced Data rates for GSM Evolution(EDGE), GSM EDGE (GERAN), and the like.

The base station 114 b in FIG. 1A may be a wireless router, Home Node B,Home eNode B, or access point, for example, and may utilize any suitableRAT for facilitating wireless connectivity in a localized area, such asa place of business, a home, a vehicle, a campus, and the like. In oneembodiment, the base station 114 b and the WTRUs 102 c, 102 d mayimplement a radio technology such as IEEE 802.11 to establish a wirelesslocal area network (WLAN). In another embodiment, the base station 114 band the WTRUs 102 c, 102 d may implement a radio technology such as IEEE802.15 to establish a wireless personal area network (WPAN). In yetanother embodiment, the base station 114 b and the WTRUs 102 c, 102 dmay utilize a cellular-based RAT (e.g., WCDMA, CDMA2000, GSM, LTE,LTE-A, etc.) to establish a picocell or femtocell. As shown in FIG. 1A,the base station 114 b may have a direct connection to the Internet 110.Thus, the base station 114 b may not be required to access the Internet110 via the core network 106.

The RAN 104 may be in communication with the core network 106, which maybe any type of network configured to provide voice, data, applications,and/or voice over internet protocol (VoIP) services to one or more ofthe WTRUs 102 a, 102 b, 102 c, 102 d. For example, the core network 106may provide call control, billing services, mobile location-basedservices, pre-paid calling, Internet connectivity, video distribution,etc., and/or perform high-level security functions, such as userauthentication. Although not shown in FIG. 1A, it will be appreciatedthat the RAN 104 and/or the core network 106 may be in direct orindirect communication with other RANs that employ the same RAT as theRAN 104 or a different RAT. For example, in addition to being connectedto the RAN 104, which may be utilizing an E-UTRA radio technology, thecore network 106 may also be in communication with another RAN (notshown) employing a GSM radio technology.

The core network 106 may also serve as a gateway for the WTRUs 102 a,102 b, 102 c, 102 d to access the PSTN 108, the Internet 110, and/orother networks 112. The PSTN 108 may include circuit-switched telephonenetworks that provide plain old telephone service (POTS). The Internet110 may include a global system of interconnected computer networks anddevices that use common communication protocols, such as thetransmission control protocol (TCP), user datagram protocol (UDP) andthe internet protocol (IP) in the TCP/IP internet protocol suite. Thenetworks 112 may include wired or wireless communications networks ownedand/or operated by other service providers. For example, the networks112 may include another core network connected to one or more RANs,which may employ the same RAT as the RAN 104 or a different RAT.

Some or all of the WTRUs 102 a, 102 b, 102 c, 102 d in thecommunications system 100 may include multi-mode capabilities, i.e., theWTRUs 102 a, 102 b, 102 c, 102 d may include multiple transceivers forcommunicating with different wireless networks over different wirelesslinks. For example, the WTRU 102 c shown in FIG. 1A may be configured tocommunicate with the base station 114 a, which may employ acellular-based radio technology, and with the base station 114 b, whichmay employ an IEEE 802 radio technology.

FIG. 1B is a system diagram of an example WTRU 102. As shown in FIG. 1B,the WTRU 102 may include a processor 118, a transceiver 120, atransmit/receive element 122, a speaker/microphone 124, a keypad 126, adisplay/touchpad 128, non-removable memory 130, removable memory 132, apower source 134, a global positioning system (GPS) chipset 136, andother peripherals 138. It will be appreciated that the WTRU 102 mayinclude any sub-combination of the foregoing elements while remainingconsistent with an embodiment.

The processor 118 may be a general purpose processor, a special purposeprocessor, a conventional processor, a digital signal processor (DSP), aplurality of microprocessors, one or more microprocessors in associationwith a DSP core, a controller, a microcontroller, Application SpecificIntegrated Circuits (ASICs), Field Programmable Gate Array (FPGAs)circuits, any other type of integrated circuit (IC), a state machine,and the like. The processor 118 may perform signal coding, dataprocessing, power control, input/output processing, and/or any otherfunctionality that enables the WTRU 102 to operate in a wirelessenvironment. The processor 118 may be coupled to the transceiver 120,which may be coupled to the transmit/receive element 122. While FIG. 1Bdepicts the processor 118 and the transceiver 120 as separatecomponents, it will be appreciated that the processor 118 and thetransceiver 120 may be integrated together in an electronic package orchip.

The transmit/receive element 122 may be configured to transmit signalsto, or receive signals from, a base station (e.g., the base station 114a) over the air interface 116. For example, in one embodiment, thetransmit/receive element 122 may be an antenna configured to transmitand/or receive RF signals. In another embodiment, the transmit/receiveelement 122 may be an emitter/detector configured to transmit and/orreceive IR, UV, or visible light signals, for example. In yet anotherembodiment, the transmit/receive element 122 may be configured totransmit and receive both RF and light signals. It will be appreciatedthat the transmit/receive element 122 may be configured to transmitand/or receive any combination of wireless signals.

In addition, although the transmit/receive element 122 is depicted inFIG. 1B as a single element, the WTRU 102 may include any number oftransmit/receive elements 122. More specifically, the WTRU 102 mayemploy MIMO technology. Thus, in one embodiment, the WTRU 102 mayinclude two or more transmit/receive elements 122 (e.g., multipleantennas) for transmitting and receiving wireless signals over the airinterface 116.

The transceiver 120 may be configured to modulate the signals that areto be transmitted by the transmit/receive element 122 and to demodulatethe signals that are received by the transmit/receive element 122. Asnoted above, the WTRU 102 may have multi-mode capabilities. Thus, thetransceiver 120 may include multiple transceivers for enabling the WTRU102 to communicate via multiple RATs, such as UTRA and IEEE 802.11, forexample.

The processor 118 of the WTRU 102 may be coupled to, and may receiveuser input data from, the speaker/microphone 124, the keypad 126, and/orthe display/touchpad 128 (e.g., a liquid crystal display (LCD) displayunit or organic light-emitting diode (OLED) display unit). The processor118 may also output user data to the speaker/microphone 124, the keypad126, and/or the display/touchpad 128. In addition, the processor 118 mayaccess information from, and store data in, any type of suitable memory,such as the non-removable memory 130 and/or the removable memory 132.The non-removable memory 130 may include random-access memory (RAM),read-only memory (ROM), a hard disk, or any other type of memory storagedevice. The removable memory 132 may include a subscriber identitymodule (SIM) card, a memory stick, a secure digital (SD) memory card,and the like. In other embodiments, the processor 118 may accessinformation from, and store data in, memory that is not physicallylocated on the WTRU 102, such as on a server or a home computer (notshown).

The processor 118 may receive power from the power source 134, and maybe configured to distribute and/or control the power to the othercomponents in the WTRU 102. The power source 134 may be any suitabledevice for powering the WTRU 102. For example, the power source 134 mayinclude one or more dry cell batteries (e.g., nickel-cadmium (NiCd),nickel-zinc (NiZn), nickel metal hydride (NiMH), lithium-ion (Li-ion),etc.), solar cells, fuel cells, and the like.

The processor 118 may also be coupled to the GPS chipset 136, which maybe configured to provide location information (e.g., longitude andlatitude) regarding the current location of the WTRU 102. In additionto, or in lieu of, the information from the GPS chipset 136, the WTRU102 may receive location information over the air interface 116 from abase station (e.g., base stations 114 a, 114 b) and/or determine itslocation based on the timing of the signals being received from two ormore nearby base stations. It will be appreciated that the WTRU 102 mayacquire location information by way of any suitablelocation-determination method while remaining consistent with anembodiment.

The processor 118 may further be coupled to other peripherals 138, whichmay include one or more software and/or hardware modules that provideadditional features, functionality and/or wired or wirelessconnectivity. For example, the peripherals 138 may include anaccelerometer, an e-compass, a satellite transceiver, a digital camera(for photographs or video), a universal serial bus (USB) port, avibration device, a television transceiver, a hands free headset, aBluetooth® module, a frequency modulated (FM) radio unit, a digitalmusic player, a media player, a video game player module, an Internetbrowser, and the like.

FIG. 1C is a system diagram of the RAN 104 and the core network 106according to an embodiment. As noted above, the RAN 104 may employ anE-UTRA radio technology to communicate with the WTRUs 102 a, 102 b, 102c over the air interface 116. The RAN 104 may also be in communicationwith the core network 106.

The RAN 104 may include eNode-Bs 140 a, 140 b, 140 c, though it will beappreciated that the RAN 104 may include any number of eNode-Bs whileremaining consistent with an embodiment. The eNode-Bs 140 a, 140 b, 140c may each include one or more transceivers for communicating with theWTRUs 102 a, 102 b, 102 c over the air interface 116. In one embodiment,the eNode-Bs 140 a, 140 b, 140 c may implement MIMO technology. Thus,the eNode-B 140 a, for example, may use multiple antennas to transmitwireless signals to, and receive wireless signals from, the WTRU 102 a.

Each of the eNode-Bs 140 a, 140 b, 140 c may be associated with aparticular cell (not shown) and may be configured to handle radioresource management decisions, handover decisions, scheduling of usersin the uplink and/or downlink, and the like. As shown in FIG. 1C, theeNode-Bs 140 a, 140 b, 140 c may communicate with one another over an X2interface.

The core network 106 shown in FIG. 1C may include a mobility managementgateway (MME) 142, a serving gateway 144, and a packet data network(PDN) gateway 146. While each of the foregoing elements are depicted aspart of the core network 106, it will be appreciated that any one ofthese elements may be owned and/or operated by an entity other than thecore network operator.

The MME 142 may be connected to each of the eNode-Bs 140 a, 140 b, 140 cin the RAN 104 via an S1 interface and may serve as a control node. Forexample, the MME 142 may be responsible for authenticating users of theWTRUs 102 a, 102 b, 102 c, bearer activation/deactivation, selecting aparticular serving gateway during an initial attach of the WTRUs 102 a,102 b, 102 c, and the like. The MME 142 may also provide a control planefunction for switching between the RAN 104 and other RANs (not shown)that employ other radio technologies, such as GSM or WCDMA.

The serving gateway 144 may be connected to each of the eNode Bs 140 a,140 b, 140 c in the RAN 104 via the S1 interface. The serving gateway144 may generally route and forward user data packets to/from the WTRUs102 a, 102 b, 102 c. The serving gateway 144 may also perform otherfunctions, such as anchoring user planes during inter-eNode B handovers,triggering paging when downlink data is available for the WTRUs 102 a,102 b, 102 c, managing and storing contexts of the WTRUs 102 a, 102 b,102 c, and the like.

The serving gateway 144 may also be connected to the PDN gateway 146,which may provide the WTRUs 102 a, 102 b, 102 c with access topacket-switched networks, such as the Internet 110, to facilitatecommunications between the WTRUs 102 a, 102 b, 102 c and IP-enableddevices.

The core network 106 may facilitate communications with other networks.For example, the core network 106 may provide the WTRUs 102 a, 102 b,102 c with access to circuit-switched networks, such as the PSTN 108, tofacilitate communications between the WTRUs 102 a, 102 b, 102 c andtraditional land-line communications devices. For example, the corenetwork 106 may include, or may communicate with, an IP gateway (e.g.,an IP multimedia subsystem (IMS) server) that serves as an interfacebetween the core network 106 and the PSTN 108. In addition, the corenetwork 106 may provide the WTRUs 102 a, 102 b, 102 c with access to thenetworks 112, which may include other wired or wireless networks thatare owned and/or operated by other service providers.

Embodiments recognize that 3rd Generation Partnership Project (3GPP)long term evolution (LTE) Releases 8/9/10/11 operate with a singleserving cell (hereafter LTE R8+) and support up to 100 Mbps in thedownlink (DL), and 50 Mbps in the uplink (UL) for a 2×2 configuration.The LTE DL transmission scheme is based on an OrthogonalFrequency-Division Multiple Access (OFDMA) air interface.

Embodiments recognize that for the purpose of flexible deployment, amongother reasons, LTE R8+ systems support scalable transmission bandwidths,one of [1.4, 2.5, 5, 10, 15 or 20] MHz. In LTE R8+, (also applicable toLTE R10+ with carrier aggregation), one or more, or each, radio frame(10 ms) may include of 10 equally sized sub-frames of 1 ms. One or more,or each, sub-frame includes 2 equally sized timeslots of 0.5 ms each.There may be either 7 or 6 OFDM symbols per timeslot, where 7 symbolsper timeslot may be used with normal cyclic prefix length, and 6 symbolsper timeslot may be used in an alternative system configuration with theextended cyclic prefix length. The sub-carrier spacing for the LTE R8/9system is 15 kHz. An alternative reduced sub-carrier spacing mode using7.5 kHz is contemplated.

Embodiments recognize that a resource element (RE) may correspond to (insome embodiments perhaps precisely) one (1) sub-carrier during one (1)OFDM symbol interval, where 12 consecutive sub-carriers during a 0.5 mstimeslot may constitute one (1) resource block (RB). Therefore, with 7symbols per timeslot, one or more, or each, RB includes 12*7=84 RE's. ADL carrier can include scalable number of resource blocks (RBs), rangingfrom a minimum of 6 RBs up to a maximum of 110 RBs. This may correspondto an overall scalable transmission bandwidth of roughly 1 MHz up to 20MHz. In some embodiments, a set of common transmission bandwidths may bespecified, e.g. 1.4, 3, 5, 10 or 20 MHz.

The basic time-domain unit for dynamic scheduling is one sub-frame thatmay include at least two consecutive timeslots. In one or moreembodiments this may be referred to as a resource-block pair. Certainsub-carriers on some OFDM symbols may be allocated to carry pilotsignals in the time-frequency grid. In some embodiments, a given numberof sub-carriers at the edges of the transmission bandwidth may not betransmitted in order to comply with spectral mask requirements, amongother reasons.

For LTE, the downlink physical channels may include, while not beinglimited to, the Physical Control Format Indicator Channel (PCFICH), thePhysical Hybrid ARQ Indicator Channel (PHICH), the Physical Data ControlChannel (PDCCH), the Physical Multicast data Channel (PMCH), thePhysical Broadcast Channel (PBCH) and the Physical Data Shared Channel(PDSCH). On the PCFICH, the WTRU receives control data indicating thesize of the control region of the DL component carrier (CC). On thePHICH, the WTRU receives control data indicating hybrid automatic repeatrequest (HARQ) Acknowledgement/Negative Acknowledgement (HARQ A/N, HARQACK/NACK or HARQ-ACK) feedback for a previous uplink transmission. Onthe PDCCH, the WTRU receives downlink control information (DCI) messagesthat may be used for the purpose of scheduling of downlink and uplinkresources. On the PDSCH, the WTRU may receive user and/or control data.For example, a WTRU may transmit on a UL CC.

For LTE, the uplink physical channels may include, while not beinglimited to, the Physical Uplink Control Channel (PUCCH), Physical RandomAccess Channel (PRACH) and the Physical Uplink Shared Channel (PUSCH).On the PUSCH, the WTRU may transmit user and/or control data. On thePUCCH, and in some case on the PUSCH, the WTRU may transmit uplinkcontrol information, (such as channel quality indicator/precoding matrixindicator/rank indicator or scheduling request (CQI/PMI/RI or SR),and/or hybrid automatic repeat request (HARQ, among others)acknowledgement/negative acknowledgement (ACK/NACK) feedback. On a ULCC, the user equipment (UE) or wireless transmit/receive unit (WTRU)(where the terms may be used interchangeably throughout thisdescription), may also be allocated dedicated resources for transmissionof Sounding Reference Signals (SRS).

In LTE R8+ systems, the WTRU may receive a cell-specific downlinkreference signal for different purposes. For example, in the case ofCell-specific Reference Signals (hereafter CRS), the WTRU may use theCRS for channel estimation for coherent demodulation of any downlinkphysical channel except for PMCH and for PDSCH configured with TM7, TM8or TM9. The WTRU may also use the CRS for channel state information(CSI) measurements. The WTRU may also use the CRS for cell-selection andmobility-related measurements. CRS may be received in any subframe.There may be one CRS for one or more, or each, of the antenna ports (1,2, or 4). A CRS may occupy the first and third last OFDM symbol of oneor more, or each, slot.

In addition, the WTRU may receive the one or more of the followingdownlink reference signals: 1) Demodulation Reference Signals (DM-RS):the WTRU-specific reference signals may be used for channel estimationfor demodulation of PDSCH with TM7, TM8 and TM9. The DM-RS may betransmitted in the resource blocks assigned to the PDSCH transmissionfor the concerned WTRU; and/or 2) CSI Reference Signals (CSI-RS): TheWTRU may use the CSI-RS for channel state information measurements.CSI-RS may be used for TM9 (or in some embodiments may only be so used),and may less densely transmitted by the network than the CRS.

The UE OR WTRU may obtain synchronization, may detect the identity ofthe cell (hereafter cell ID) and may determine the length(normal/extended) of the cyclic prefix using synchronization signals(which may be based on the difference in duration between the primaryand the secondary synchronization signals). The UE OR WTRU may receivethe Master Information block (hereafter MIB) on the PBCH; the MIBcontains PHICH information, downlink bandwidth and system frame number.The UE OR WTRU can also use the PBCH to blindly detect the number oftransmit antenna port(s) which detection is verified using the PBCH CRC.

In an LTE system, the NW may control physical radio resources using thePDCCH; control messages may be transmitted using specific messages, e.g.data control information (DCI) messages. The UE OR WTRU may determinewhether or not it may be useful to act on control signaling in a givensub-frame by monitoring the PDCCH for specific DCIs scrambled using aknown radio network temporary identifier (hereafter RNTI) in specificlocations, or search space, using different combinations of physicalresources (e.g., control channel elements—hereafter CCEs) based onaggregation levels (hereafter AL, one or more, or each, corresponding toeither 1, 2, 4, or 8 CCEs). A CCE includes of 36 QPSK symbols, or 72channel coded bits.

In one or more embodiments, the PDCCH may be conceptually separated intwo distinct regions. The set of CCE locations in which a UE or WTRU mayfind DCIs it may act on may be referred to as a Search Space (hereafterSS). The SS may be conceptually split into the common SS (hereafter CSS)and UE OR WTRU-specific SS (hereafter UESS); the CSS may be common toone or more, or all, UEs monitoring a given PDCCH, while the UESSdiffers from one UE OR WTRU to another. In some embodiments, both SS mayoverlap for a given UE OR WTRU in a given sub-frame. This may be afunction of the randomization function, and this overlap may differ fromone sub-frame to another.

The set of CCE locations that makes up the Common Search Space (CSS),and its starting point, may be a function of the cell identity and thesub-frame number. For LTE R8/9, DCIs may be sent with AL4 (4 CCEs) orAL8 (8 CCEs) in the CSS (or in some embodiments may only be so sent).For a sub-frame for which the UE OR WTRU monitors the PDCCH, the UE ORWTRU may attempt to decode 2 DCI format sizes (e.g. formats 1A and 1C,see below, and also format 3A used for power control) in up to 4different sets of 4 CCES for AL4 (e.g., 8 blind decoding) and up to 2different sets of 8 CCEs for AL8 (e.g., 4 blind decoding) for a total ofat most 12 blind decoding attempts in the CSS. The CSS corresponds toCCEs 0-15, implying four decoding candidates for AL4 (e.g., CCEs 0-3,4-7, 8-11, 12-15) and two decoding candidates for AL8 (CCEs 0-7, 8-15).

The set of CCE locations that makes up the UE OR WTRU-Specific SearchSpace (UESS), and its starting point, may be a function of the UE ORWTRU identity and the sub-frame number. For LTE R8+, DCIs may be sentwith AL1, AL2, AL4 or AL8 in the UESS. For a sub-frame for which the UEor WTRU monitors the PDCCH, the UE or WTRU may attempt to decode 2 DCIformats in up to 6 different CCES for AL1 (e.g., 12 blind decoding), upto 6 different sets of 2 CCEs for AL2 (e.g., 12 blind decoding), up to 2different sets of 8 CCEs for AL8 (e.g., 4 blind decoding) and up to 2different sets of 8 CCEs for AL8 (e.g., 4 blind decoding) for a total ofat most 32 blind decoding attempts in the UESS.

Which DCI formats the UE or WTRU decodes may depend on the configuredtransmission mode (e.g. whether or not spatial multiplexing may beused). There may be a number of different DCI formats, e.g., format 0(UL grant), formats 1 (non-MIMO), formats 2 (DL MIMO) and formats 3(power control). Exemplary detailed format of the control messages maybe defined in TS 36.212, section 5.3.3.1. The version of one or more, oreach, DCI format(s) the UE or WTRU decodes may be governed at least inpart by the configured transmission mode (e.g. modes 1-7 for Release 8and Release 9).

A summary list with exemplary usage is presented below:

DCI format 0 (UL grant)

DCI format 1 (DL assignment)

DCI format 1A (compact DL assignment/PDCCH order for random access)

DCI format 1B (DL assignment with precoding info)

DCI format 1C (very compact DL assignment)

DCI format 1D (compact DL assignment with precoding info+power offsetinfo)

DCI format 2 (DL assignment for spatial multiplexing)

DCI format 2A

DCI format 3 (TPC for PUCCH/PDSCH, two bits)

DCI format 3A (TPC for PUCCH/PDSCH, single bit)

A table illustrating examples of the different DCI sizes resulting fromdifferent system bandwidth configurations is provided in FIG. 2.

In LTE R8+ systems, whether the control signaling received on PDCCHpertains to the uplink component carrier or to the downlink componentcarrier may be related to the format of the DCI decoded by the UE orWTRU and the DCI formats may be used to control the UEs communication onthe uplink component carrier and on the downlink component carrier ofthe cell on which the UE or WTRU is connected to. A UE or WTRU canrequest radio resources for an uplink transmission by sending ascheduling request (hereafter SR) to the eNB; the SR may be transmittedeither on dedicated resources (hereafter D-SR) on the PUCCH ifconfigured, or using the Random Access procedure (hereafter RACH)otherwise (hereafter RA-SR).

The following terminology may be used herein. In some embodiments, a“point” may refer to a set of geographically co-located transmitantennas. In one or more embodiments described herein, this definitionmay be slightly generalized, so that a “point” may also refer to a setof geographically co-located antennas, whether or not they transmit orreceive.

An “intended reception point” or “destination point” of a first UE orWTRU transmission may refer to a point at the network side, or in someembodiments a second UE or WTRU, which may expect to receive and processthis first UE or WTRU transmission. In one or more embodiments, thedestination point may be identified by the first UE or WTRU bycharacteristics of a signal (such as a cell-specific reference signal,CSI-RS, or, in case the destination point corresponds to a second WTRU,a WTRU-specific reference such as DM-RS, SRS, PRACH preamble or othertype of signal) transmitted by this destination point. Embodimentscontemplate the use and meanings of, without limitation of applicabilitythereof, the following terms:

Component Carrier (CC), DL CC and UL CC;

Primary Cell (PCell), PCell DL, PCell UL and Secondary Cell (SCell),SCell DL, SCell UL;

Cell, serving cell, primary serving cell and secondary serving cell;

When referred to hereafter, the term “Component Carrier (CC)” mayinclude, without loss of generality, a frequency on which the UE or WTRUoperates. For example, a UE or WTRU may receive transmissions on adownlink CC (hereafter “DL CC”); a DL CC may comprise of a plurality ofDL physical channels. As another example, a UE or WTRU may performtransmissions on an uplink CC (hereafter “UL CC”); a UL CC may compriseof a plurality of UL physical channels, as described above.

A cell may minimally consists in a DL CC which may be linked to a UL CCbased on the system information (SI) received by the UE or WTRU eitherbroadcasted on the DL CC or possibly using dedicated configurationsignaling from the network. For example, when broadcasted on the DL CC,the UE or WTRU may receive the uplink frequency and bandwidth of thelinked UL CC as part of the system information element (e.g. when inRRC_IDLE for LTE, or when in idle/CELL_FACH for WCDMA, e.g., when the UEor WTRU does not yet have a radio resource connection to the network).

When referred to hereafter, the term “Primary Cell (PCell)” includes,without loss of generality, the cell operating on the primary frequencyin which the UE or WTRU performs the initial access to the system, e.g.,the cell in which it either performs the initial connectionestablishment procedure or initiates the connection re-establishmentprocedure, or the cell indicated as the primary cell in the handoverprocedure, or the like. It may also correspond to a frequency indicatedas part of the radio resource connection configuration procedure. Somefunctions may be (or in some embodiments may only be) supported on thePCell. For example, the UL CC of the PCell may correspond to the CCwhose physical uplink control channel resources may be configured tocarry one or more, or all, HARQ ACK/NACK feedback for a given UE orWTRU.

For example, in LTE the UE or WTRU may use the PCell to derive theparameters for the security functions and for upper layer systeminformation such as NAS mobility information. Other functions that maybe supported (or in some embodiments may only be supported) on the PCellDL include system information (SI) acquisition and change monitoringprocedures on the broadcast channel (BCCH), and paging.

When referred to hereafter, the term “Secondary Cell (SCell)” includes,without loss of generality, the cell operating on a secondary frequencywhich may be configured once a radio resource control connection may beestablished and which may be used to provide additional radio resources.System information relevant for operation in the concerned SCell may beprovided using dedicated signaling when the SCell may be added to the UEor WTRU's configuration. Although the parameters may have differentvalues than those broadcasted on the downlink of the concerned SCellusing the system information (SI) signaling, this information may beherein referred to as SI of the concerned SCell independently of themethod used by the UE or WTRU to acquire this information.

When referred to hereafter, the terms “PCell DL” and “PCell UL”corresponds to, without loss of generality, the DL CC and the UL CC ofthe PCell, respectively. Similarly, the terms “SCell DL” and “SCell UL”corresponds to the DL CC and the UL CC (if configured) of a SCell,respectively.

When referred to hereafter, the term “serving cell” includes, withoutloss of generality, a primary cell (e.g., a PCell) or a secondary cell(e.g., a SCell). More specifically, for a UE or WTRU that may not beconfigured with any SCell or that does not support operation on multiplecomponent carriers (e.g., carrier aggregation), there may be (or in someembodiments perhaps there may only be) one serving cell comprising ofthe PCell; for a UE or WTRU that is configured with at least one SCell,the term “serving cells” may include the set of one or more cellscomprising of the PCell and one or more, or all, configured SCell(s).

In one or more embodiments, when a UE or WTRU may be configured with atleast one SCell, there may be at least one PCell DL and at least onePCell UL and, for one or more, or each, configured SCell, there may beat least one SCell DL and, in one or more embodiments, perhaps one SCellUL (e.g., if configured).

One or more embodiments contemplate one or more techniques that mayallow the UE or WTRU to select the destination point or a set ofdestination points of a transmission on a dynamic basis. Thesetechniques may allow the adjustment of certain characteristics of anuplink transmission that may facilitate reception and decoding at thisat least one destination point. For instance, the characteristics mayinclude transmission power, transmission timing, and/or a property of areference signal used for demodulation purpose or for sounding purposesuch as its base sequence, its cyclic shift or an orthogonal cover code.Such techniques may support capacity optimizations from the networkperspective, as well as fallback mechanisms for robust operation fromthe UE or WTRU perspective.

Other methods address problems related to destination point selectionand other functionalities that arise when multiple potential destinationpoints may be possible for a UE or WTRU transmission. For instance, itmay be useful to be determined how HARQ retransmissions may be handled.In addition, the current power headroom reporting mechanism may notallow the network to make optimal uplink scheduling decisions whenmultiple potential reception points exist. Another problem stems fromthe possibility that the UE or WTRU loses connectivity with at least onedestination point, which could result in excessive interference if theUE or WTRU attempts transmissions to this destination point.

Other methods address issues that arise when operating in a deploymentwith multiple potential destination points. For example, the schedulingrestriction of allocating the same BW assignment between twoco-scheduled UE or WTRU's to achieve orthogonality may become moresevere.

In particular, when multiple UEs may be co-scheduled for uplinktransmission within a cell in the same subframe, it may be useful tohave mutual orthogonality, (or significantly reduced cross correlation),among the reference signals used for one or more, or each, UE or WTRU inorder to minimize the cross interference. In current 3GPP standardReleases, this may be achievable by allocating the same base sequencegroup and different cyclic shift (CS) setting, if identical bandwidth(BW) resources may be shared to one or more, or all, co-scheduled UEs.To improve network scheduling efficiency, particularly for inter-cellMU-MIMO operation occurring in the multipoint uplink reception, thenetwork may be required to schedule UEs with unpaired BWs which may bepartially overlapped. FIG. 3 shows two example scenarios of the unpairedBW allocation for two UEs.

As result of the unpaired BW allocation, the original orthogonalityachieved by different CS settings may be lost as large peakcross-correlation is sometimes observed among the reference signals usedfor one or more, or each, UE or WTRU. The problem stems from the factthat the correlation peak drifts to a different location in time domainbecause of change of RB allocation. This drifted peak may penetrateother CS regions assigned to RS of another UE or WTRU, creatingsignificant interference to it. This is illustrated in an example shownby FIG. 4, where equal BW lengths of 12 RBs may be used and the overlapportion is 6 RBs. As seen from FIG. 4, the amount of drift may be fairlylarge, (sometimes wrapped around). In addition, the correlation peakbecomes wider because of the window effect proportional to the width ofthe overlap portion, which may further degrade the correlationperformance, particularly when the overlap portion of two RSs may bevery small.

Methods are also provided to address issues arising in deployments withmultiple potential destination points where cyclic shift hopping (CShopping) may be in use in some of these destination points. Thus, it maybecome more difficult to assign a CS for the transmission of a UE orWTRU that does not result in excessive interference towards thesepoints.

Cyclic hopping may be applied to the demodulation reference signal(DMRS) in order to randomize its interference to other UEs. In current3GPP standard, for one or more, or each, UE or WTRU, a cyclic shiftα_(λ) for a layer indexed by λ is defined according to:

${\alpha_{\lambda} = \frac{2\pi\; n_{{cs},\lambda}}{12}},{n_{{cs},\lambda} = {\left( {n_{DMRS}^{(1)} + n_{{DMRS},\lambda}^{(2)} + {n_{pn}\left( n_{s} \right)}} \right){mod}\mspace{14mu} 12}}$${{where}\mspace{14mu} n\frac{(1)}{{DMRS}^{\prime}}},{n\frac{(2)}{{DMRS},\lambda}}$may be respectively the UE or WTRU-specific and layer-specificparameters andn_(PN)(n_(s)) is the cell-specific CS hopping pattern defined by:

${n_{PN}\left( n_{s} \right)} = {\sum\limits_{i = 0}^{7}\;{{c\left( {{8\; N_{symb}^{UL}n_{s}} + i} \right)}2^{i}}}$which is initiated by:

$c_{init} = {\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor + {f_{ss}^{PUSCH}.}}$In some embodiments, the sequence-shift pattern f_(ss) ^(PUSCH) mayshare the same value with that used in defining the base sequence group,for example.

For inter-cell multi-user multiple-input multiple-output (MU-MIMO)operation, in order to enhance orthogonality of reference signals acrossmultiple cells or points, it may be beneficial to allow dynamicassignment of base sequences to the co-scheduled UEs. Thus f_(ss)^(PUSCH) may not be appropriate for defining CS hopping because it maybe now varying time or may no longer be cell specific, for example.

The methods described herein may be taken alone or in combination,explain how a UE or WTRU can transmit different types of uplink channelsor signals in a system deployment where multiple destination points mayexist.

Upon performing a transmission of a given channel or signal in asubframe, the UE or WTRU may determine transmission characteristics thatmay be dependent on an Uplink Transmission Context (hereafter UTC)selected out of a set of at least one UTC. Described herein are variousembodiments of methods of selecting a UTC.

In various embodiments, the UE or WTRU may use the selected UTC toperform a transmission for a given channel or signal such that it maydetermine at least one of the following transmission characteristics: Anuplink frequency and/or a bandwidth for the said transmission; Atransmission power to apply to the said transmission; A timing advance(or timing alignment) to apply to the said transmission; At least oneproperty that may be specific to the transmitted channel or signal, suchas: (i) A property of at least one demodulation reference signal (e.g.cyclic shift, sequence group, antenna port), e.g. for PUSCH or SRS(periodic or aperiodic); (ii) A transmission format and/or resource,e.g. in case of a PUCCH transmission; and (iii) A property of at leastone random access preamble, e.g. in case of a PRACH transmission.

A UTC may be defined such that it represents information that enablesthe UE or WTRU to perform uplink transmissions according to the selectedUTC. The UTC may conceptually be divided in terms of at least one of thefollowing types of information associated to the concerned UTC:

-   -   UTC parameters: a set of one or more parameters including, but        not limited to, parameters of a UE or WTRU's configuration such        as semi-static parameters configured by RRC (e.g. a maximum        transmission power which may be used to determine a transmission        power for a transmission for the concerned UTC), or the like;    -   UTC properties: a set or one or more properties including, but        not limited to, properties derived from a UE or WTRU's        configuration (e.g. a DL path loss and/or timing reference        derived from a grouping function), from a procedure performed by        the UE or WTRU (e.g. a DL path loss estimate derived from a DL        PL reference which may be used to determine a transmission power        for a transmission for the concerned UTC) or the like; and/or    -   UTC variables: a set of one or more variables including, but not        limited to, state variables (e.g. whether or not a UTC may be in        an activated state), timers (e.g. a timer related to the        validity of a timing advance value) or the like.

In other words, an Uplink Transmission Context may be conceptuallyrepresented as to include at least one of a set of semi-staticparameters, values determined by the UE or WTRU in relation to a giventransmission and in one or more embodiments may be based on aconfiguration of a parameter, and/or variables that may be maintainedand updated by the UE or WTRU in relation to the concerned UTC.

The representation described herein does not limit the applicability ofthe methods described herein to different representation of anequivalent description of the UTC and its related methods.

An UTC may be associated to one or more types of uplink channels oruplink signals according to at least one of the following:

-   -   Uplink channel (or transmission signal)-specific: For example, a        UTC (or parts thereof) may be applicable to a given uplink        channel e.g. a UE or WTRU may be configured with one or more UTC        for one or more, or each, of a PUSCH, a PUCCH, a PRACH or a SRS        configuration;    -   Serving cell-specific: For example, a UTC (or parts thereof) may        be applicable to a plurality of uplink transmissions for a given        serving cell of the UE or WTRU's configuration, in which case        the UTC may include aspects that may be common to one or more,        or all, transmissions (e.g. a DL PL and/or timing reference)        and/or aspects that may be specific to a given type of        transmission (e.g. a transmission power offset to apply e.g. for        SRS transmissions);    -   Group of cell-specific: For example, a UTC (or parts thereof)        may be applicable to transmission(s) for one or more serving        cells of a UE or WTRU's configuration, in which case the UTC may        include aspects that may be common to one or more, or all,        transmissions for the group of serving cells (e.g. a DL PL        and/or timing reference); and/or    -   A combination of the above: For example, a UTC (or parts        thereof) may be applicable according to one or more of the        following: The UTC may be applicable to a given serving cell,        e.g. it may be configured for a SCell; The UTC may be applicable        to a given uplink channel, e.g. it may be applicable to        transmissions on PUSCH; For example, one or more, or each, UTC        may include different PtRS and maximum power; The UE or WTRU may        be configured with a plurality of UTC for the PUSCH of the        concerned cell; The UE or WTRU may use selection methods such as        those described herein to determine what UTC may be applicable        for a given transmission.

As another example, a UTC (or parts thereof) may be applicable accordingto the following: The UTC may be applicable to a plurality of servingcells configured with uplink resources, e.g. it may be configured forone or more, or all, SCells of the same TA group; The UTC may beapplicable to one or more, or all, uplink transmissions, e.g. it may beapplicable to transmissions on PUSCH, PRACH and SRS; For example, one ormore, or each, UTC may include different PtRS, DL PL reference and DLtiming reference; The UE or WTRU may be configured with a plurality ofUTC for the concerned cells; The UE or WTRU may use selection methodssuch as those described herein to determine what UTC may be applicablefor the transmissions on uplink resources of a concerned cell.

As another example, a UTC (or parts thereof) may be applicable accordingto the following: The UTC may be applicable to a plurality of channels(e.g. PUSCH/PUCCH/PRACH) for one serving cell; The UE or WTRU may beconfigured with a plurality of UTC for the group of channels; The UE orWTRU may use selection methods such as those described herein todetermine what UTC to use for one or more, or all, the channels withinthe group; The UE or WTRU may be further configured with another UTCthat may be applicable to another type of channel or transmission type(e.g. SRS); The UE or WTRU may be configured with a plurality of UTC forthe transmission type SRS; The UE or WTRU may use selection methods suchas those described herein to determine which UTC to use for SRStransmission (e.g. the type of SRS may be used to determine which UTC touse).

UTC Parameters: The parameters that may be associated to an UTC mayinclude at least one of the following configuration parameters. Some ofthese parameters may be defined to be common to more than one UTC, or toone or more, or all, UTC's. These may include L1/Physical layerparameters, L2/MAC parameters, and/or L3/RRC parameters.

L1/Physical layer parameters may be at least one of: at least onedownlink Point Reference Signal (hereafter PtRS), where a PtRS mayrepresent an intended reception point of a given transmission and incase of more than one intended reception point, more than one PtRS maybe included; a Physical Cell Identity, where, the UE or WTRU may, forexample, use at least one cell identity in the generation of certainuplink signals or channels (e.g. PUCCH, DM-RS, SRS) and this identitymay or may not correspond to the identity of a serving cell which theUTC may be applicable to; other parameters used in the generation ofcertain uplink signals may include use parameters corresponding to thatcontained in the PUSCH-Config information element of existing systems,such as cyclicShift, groupAssignmentPUSCH (ΔSS), Activate-DMRS-with OCC,Sequence-hopping-enabled, groupHoppingEnabled, pusch-HoppingOffset,n-SB, hopping Mode for the generation of DM-RS in PUCCH, DM-RS in PUSCHand/or PUSCH, which may have the same interpretation as in existingsystems. The UE or WTRU may also use new (e.g., contemplated byembodiments) parameters to generate such signals, as described herein.In another example, the UE or WTRU may use parameters corresponding tothat contained in the PUCCH-Config information element of existingsystems, such as n1PUCCH-AN(N_(PUCCH) ⁽¹⁾), n1PUCCH-AN-CS-List, nCS-An,and the like; power control parameters that the UE or WTRU may, forexample, use in combination with PtRS measurements to determine thetransmission power to apply to a given transmission. For example, suchparameters may include a maximum transmission power (Pmax) applicable toa transmission using the concerned UTC, and/or a reference transmissionpower for one or more, or each, TpRS, indicating the transmission powerof this TpRS for path loss estimation purposes; Scheduling-relatedparameters that the UE or WTRU may, for example, determine at least oneaspect of the decoding of DCI format on a PDCCH corresponding to theconcerned UTC, which DCI format may possibly contain downlinkinformation that triggers the uplink transmission and/or may possiblycontain TPC commands applicable to at least one aspect of the concernedUTC. For example, the UE or WTRU may determine at least one search spaceof the concerned PDCCH. In one or more embodiments may, different searchspace may correspond to different UTC. The UE or WTRU may determine atleast one set of DCI formats of the concerned PDCCH. In one or moreembodiments, different DCI formats and/or contents may correspond todifferent UTCs. Alternatively, depending on an UTC activation state fora given serving cell, DCI decoding may use different DCI formatscorresponding to the active (or selected) UTC. The UE or WTRU maydetermine at least one RNTI of the concerned PDCCH. In one or moreembodiments may, different RNTI may correspond to different UTCs.

The L2/MAC parameters, for example, may include at least one of: timingparameters, which the UE or WTRU may, for example, determine the DLTiming reference for a given transmission based on the selected UTC; andscheduling-related parameters, which the UE or WTRU may, for example,determine the RNTI to monitor for the PDCCH corresponding to a given UTCbased on the activation state of the concerned UTC.

The L3/RRC parameters, e.g. at least one of: an identity of the UTC,which the UE or WTRU may, for example, use as an identity of an UTC,e.g. for the purpose of adding, modifying and/or removing an UTC; or oneor more selection criterion or parameters of the UTC, which the UE orWTRU may, for example, use as a configuration for RLM operation as a wayto determine whether or not a UTC may be selected for an uplinktransmission.

For one or more, or each, of the above, the UTC may include a distinctset of parameters that may be specific to one or more, or each, type ofuplink transmission (e.g. one set for PRACH, PUSCH, aperiodic SRS,periodic SRS, PUCCH).

Embodiments contemplate UTC properties. The properties that may beassociated to an UTC may include at least one of the following: Forexample, for at least one channel or signal, whether transmission ofthis channel or signal may be allowed or not for this UTC. For instance,transmission of PUCCH may or may not be possible for the UTC. For atleast two channel(s) or signal(s), whether simultaneous transmission ofthese channel(s) or signal(s) may be allowed or not in the same subframe(such as PUCCH with PUSCH, PUCCH with SRS, etc.). For example, for atleast one channel or signal, a DL path loss reference and/or a DL timingreference and/or a TA group may be associated to a given UTC.

Embodiments contemplate UTC variables. In addition to the above, thefollowing state variables associated to an Uplink Transmission Contextmay be utilized in the determination of transmission characteristics: Apower control adjustment state for the UTC to be used in thedetermination of transmission power in case this UTC may be selected(e.g. a TPC accumulation); A transmission timing adjustment state (e.g.a TA adjustment or TA accumulator) for the UTC, possibly with respect toa reference signal such as its PtRS. The UE or WTRU may, for example,determine the TA offset to apply to a given transmission based on theselected UTC; A timing advance timer for the UTC (e.g. a TAT); Anactivation state of the Transmission Context, to be used for the purposeof selecting an UTC; and/or A connectivity state of the UTC, to be usedfor the purpose of determining whether selection of this UTC may bepossible, among other contemplated purposes.

At least one of the above configuration parameters and state variablesmay be shared within a Group of at least one UTC. For instance, a groupof UTCs may be defined for one or more, or all, UTCs sharing the samePtRS. In this case, such group of UTC's may also share the sametransmission timing adjustment state, timing advance timer, andconnectivity state.

An UTC may be seen as corresponding to at least one “intended receptionpoint” or “destination point” for the UE or WTRU transmission, under theassumption that the PtRS is transmitted from a “transmission point”corresponding to one of the destination points. At least one such pointat the network may be expected to receive and process this UE or WTRUtransmission. Thus, a PtRS of an UTC may also correspond to a downlinkreference signal associated to a transmission point. Such transmissionpoint may itself be associated with its own configuration definingcharacteristics of downlink transmissions that may be received by the UEor WTRU (or “Downlink Transmission Context”). It may be possible to linka unique UTC to a given Downlink Transmission Context. If such linkagemay be defined, some characteristics of the UTC (such as those used forthe determination of search spaces for PDCCH, or the identity of a PtRS)may be defined as part of the corresponding Downlink TransmissionContext. The set of configured UTCs for a UE or WTRU may or may not beassociated with the same cell identity.

Downlink Point Reference Signal (PtRS): A Point Reference Signal (PtRS)may be defined as a downlink Reference Signal that may be measured bythe UE or WTRU on a given downlink carrier. The UE or WTRU may use thePtRS for the purpose of performing at least one of the following: Pathloss estimation, e.g. the UE or WTRU may use the PtRS as the DL PLreference; Power control; Timing alignment, e.g. the UE or WTRU may usethe PtRS as the DL timing reference; Measurements, e.g. received poweror quality; Radio link monitoring and determination of connectivitystate; UTC selection or restriction.

A PtRS configured for an UTC may include a reference signal such as onealready defined in existing systems, including a common reference signal(CRS) or a CSI-RS reference signal. Alternatively, the PtRS may includeany other reference signal, such as one that may be optimized for thepurpose of path loss estimation for an UTC. As example of such optimizedsignal, this reference signal may be transmitted in a subset of thephysical resource blocks, for instance in 1 out of N physical resourceblocks with an offset that may be depending on an antenna port index. Inthe time domain, the reference signal may be transmitted morefrequently, such as in every time slot or every subframe. Suchconfiguration sparse in frequency domain but dense in time domain may bebeneficial for the purpose of path loss estimation where frequencyresolution may not be critical but tracking time fast variations may beuseful. In one or more embodiments, a PtRS may be transmitted on atleast one antenna port, each of which may be identified with an antennaport index.

Embodiments contemplate one or more techniques to realize theconfiguration of a UTC in the UE or WTRU. Radio Resource Configurationaspects: The UE or WTRU may be configured, e.g. using a proceduresimilar to the state-of-the-art RRC connection reconfiguration procedureand/or a RRCConnectionReconfiguration message (with or without themobilityControlIinfo information element) to operate on a primaryserving cell (e.g. a PCell) and zero or more additional serving cells(e.g. SCells) for operation according to the principles of carrieraggregation.

In addition, for a given serving cell, the UE or WTRU may additionallybe configured with one or a plurality of UTCs. In one or moreembodiments, this may be performed (or in some embodiments may only beperformed) for a serving cell with configured uplink resources. Forexample, a UE or WTRU may be configured with a plurality of UTC for aserving cell, where the selected UTC may be applicable to any uplinktransmission on radio resources of the concerned cell.

In one or more embodiments may, a UTC configuration may be applicable toa specific type of uplink channel, e.g. PUCCH, PUSCH, PRACH and/or to aspecific type of uplink transmissions e.g. SRS for a given serving cell.For example, a UE or WTRU may be configured with a plurality of UTC forthe PUCCH channel of a PCell, while a single UTC may be configured forPRACH and PUSCH for the concerned serving cell. In other words,different type of uplink transmission may be configured with differentUTC, or none (which resulting configuration may represent a defaultUTC), for a given serving cell.

In one or more embodiments may, a UTC configuration may be applicable toa specific type of uplink transmission and/or uplink channel, e.g.PUCCH, PUSCH, PRACH or SRS across a plurality of serving cells. Forexample, the UE or WTRU may be configured with a plurality of UTCapplicable to the PUSCH transmission of one or more, or all, servingcells of the UE or WTRU's configuration. Alternatively, the UTC may beapplicable to a subset of serving cells, for example a plurality of UTCapplicable to the PUSCH transmission of one or more, or all, SCells ofthe UE or WTRU's configuration.

In one or more embodiments may, a subset to which a UTC may beapplicable may be based on grouping. For example, a UE or WTRU may beconfigured with a UTC for PUSCH channel of a plurality of serving cellswithin a group of cells, e.g. for one or more, or all, SCells that maybe configured as part of the same Timing Advance Group (TA Group), orbased on an explicit grouping configuration received by RRC signaling.

A UTC group may have at least one of the following characteristics incommon: DL timing reference, and/or Timing Advance, and/or TA timer; DLpath loss reference and/or path loss estimate; DL reference for radiolink monitoring; for example, when the RLM function of a DL referencecorresponding to a group of UTC may determine that the reference may beno longer suitable, the UE or WTRU may perform a number of actions thatmay be applicable to one or more (or all) UTC of the same group. Forexample, the UE or WTRU may deactivate the corresponding UTC; Powercontrol parameters, e.g. the nominal desired transmit power Po, and/orthe maximum power Pcmax, and/or TPC accumulation; RNTI to identifycontrol signaling applicable a UTC of the concerned group; and/or anidentity of the group.

The UE or WTRU may receive RRC signaling that includes aPhysicalConfigDedicated information element that configures the radioresources of the UE or WTRU for the PCell. In addition, the UE or WTRUmay receive RRC signaling that includes a PhysicalConfigDedicatedSCellinformation element that configures the radio resources of the UE orWTRU for one or more SCells. Such information element may includeconfiguration information related to uplink channels and transmissions,e.g. pucch-ConfigDedicated, pusch-ConfigDedicated,uplinkPowerControlDedicated, tpc-PDCCH-ConfigPUCCH,tpc-PDCCH-ConfigPUSCH, cqi-ReportConfig, soundingRS-UL-ConfigDedicated,antennaInfo, schedulingRequestConfig, cqi-ReportConfig, csi-RS-Config,soundingRS-UL-ConfigDedicatedAperiodic, ul-AntennaInfo and the likes.

The UE or WTRU may receive a UTC configuration in aPhysicalConfigDedicated information element and/or in aPhysicalConfigDedicatedSCell information element.

In one embodiment, a given channel may be configured with a plurality ofUTC by including multiple parameters for the concerned channel insidethe physical channel configuration applicable to a given serving cell.In one or more embodiments may, the state-of-the-art configuration mayimplicitly be the default UTC configuration, while additional UTC for agiven channel may be indexed according to their relative position insidea list of additional UTC. FIG. 5 depicts an example for a Pcell.

In another embodiment, a given UTC may be configured and may include aplurality of channels UTC for a given serving cell. In one embodiment,the state-of-the-art configuration may implicitly be the default UTCconfiguration, while additional UTC for a given serving cell may beindexed according to their relative position inside a list of additionalUTC. FIG. 6 depicts an example for a Pcell.

In another embodiment, the UE or WTRU may be configured with a pluralityof “sub-cell” configuration for a given serving cell, by using multipleinformation elements. In one or more embodiments may, an informationelement may be associated to a given serving cell by using the same cellidentity e.g. there may be multiple configuration with the sameservCellID. In one or more embodiments may, the order of the informationelements for the serving cell configuration (e.g. associated with agiven servCellID) may be used to derive an identity of the UTC for thegiven serving cell. For example, for PCell (which implicitly has id “0”)the configuration may include a plurality of PhysicalConfigDedicated(and/or also “Common”) information elements, one for one or more, oreach, UTC applicable to the PCell. For example, similarly, for a SCellidentified with an explicit servCellID the configuration may include aplurality of PhysicalConfigDedicatedSCell (and/or also “Common”)information elements, one for one or more, or each, UTC applicable tothe concerned SCell.

In another embodiment, an information element may be defined for UTCs,which IE may include configuration parameters for a single channel ortype of uplink transmissions, or a plurality thereof.

In another embodiment, the UTC configuration may be provided as part ofthe power control configuration. For one or more, or each, UTC a new(e.g., contemplated by embodiments) power control dedicated IE may beadded that includes the parameters required for one or more, or all,channels and transmission types. One example is shown below, in whichthe pathlossReferencePointLinking-rxx correspond to the downlink pointreference signal for a given UTC. The reference signal information asdescribed above may have been provided as part of a downlinkconfiguration for a transmission point (e.g. for example UTC1corresponds to transmission point 1 and UTC 2 to transmission point 2)or they may have been explicitly provided for one or more, or each, UTC.

FIG. 7 depicts exemplary UplinkPowerControl information elements.

The UTC configuration for a given channel or transmission type may befurther realized using one or a combination of the methods describedbelow with respect to Physical layer aspects.

For a given serving cell (e.g. Pcell or Scell) the principle of a UTCfor a given channel and/or transmission type may be implemented usingone or a combination of the methods described below.

An additional column for one or more, or each, TM may be added to Table8-3 of 36.213 (copied below). Embodiments contemplate multiple UTCs perTransmission Mode (TM). The UE or WTRU may be configured with a singleTM per configured serving cell (e.g. TM 1 or TM 2 for PUSCH).Additionally, the UE or WTRU may be configured for one or more, or each,TM with a plurality of UTC, where one or more UTC(s) may be configuredfor one or for a subset of channels or transmission types, using forexample one or a combination of the methods described below.

TABLE 8-3 PDCCH and PUSCH configured by C-RNTI Transmission Transmissionscheme of PUSCH mode DCI format Search Space corresponding to PDCCH Mode1 DCI format 0 Common and Single-antenna port, port 10 UE or WTRUspecific by (see subclause 8.0.1) C-RNTI Mode 2 DCI format 0 Common andSingle-antenna port, port 10 UE or WTRU specific by (see subclause8.0.1) C-RNTI DCI format 4 UE or WTRU specific by Closed-loop spatialmultiplexing C-RNTI (see subclause 8.0.2)

The above table may be expanded with multiple table 8-3s for a servingcell. Embodiments contemplate Multiple UTCs per serving cell. The UE orWTRU may be configured with a plurality of UTCs for a configured servingcell. In this case, a UTC may be conceptually viewed as a “sub-cell”within the configuration of a serving cell. In one or more embodimentsmay, each UTC may be configured with a single TM.

The above table may be expanded with additional rows for a serving cell.Embodiments contemplate Multiple TMs per serving cell. The UE or WTRUmay be configured with additional transmission mode(s), which may beintroduced in addition to LTE R10 TM1 and TM2 for uplink operation. Forone or more, or each additional TM, a plurality of UTC may beconfigured. For example, such additional TM may be configured such thate.g. a DCI format (and/or format type) indicates the use of a specificUTC. More specifically, for one or more, or each, DCI format 0 and 4, aUTC may be configured (or a default UTC may be used) and possibly a new(e.g., contemplated by embodiments) DCI format may be introduced thatmay have one or a plurality of UTC configured. In some embodiments, theUTC to be used within the new (e.g., contemplated by embodiments) DCIformat may be determined according to the embodiments described herein.

In particular, the above may be applicable to the configuration ofUTC(s) for PUSCH channels.

In one or more embodiments, the principle of UTC may be implementedaccording to one or more of the following:

-   -   One or more UTCs per channel: The UE or WTRU may be configured        with a plurality of UTC per channel (e.g. PUCCH, PRACH, or        possibly also PUSCH) or per transmission type (e.g. SRS) as part        of configuration parameters in the UL configuration. For        example, the UE or WTRU may be configured with a UTC or a subset        thereof as part of a PUCCH configuration. The UTC may include an        activation state for the PUCCH, as well as a set of configured        PUCCH resources indexed using an ARI; the ARI and/or the PUCCH        activation state may be used to determine the PtRS and/or the        applicable UTC for a PUCCH transmission. For example, the UE or        WTRU may be configured with a UTC or a subset thereof as part of        a SRS configuration, for periodic SRS and/or for aperiodic SRS.        The UTC may include an activation state for the concerned SRS        configuration. More specifically, the UE or WTRU may be        configured with a separate UTC configuration for aperiodic SRS        transmissions and periodic SRS transmissions. The type of SRS        (e.g. SRS type 0 or SRS type 1) may thus be used to determine        what UTC to apply to the SRS transmission (possibly including        what PtRS to use as a reference) for a given serving cell. In        addition, the UE or WTRU may be configured with a plurality of        configuration for either type, possibly one or more, or each,        with a different UTC. For example, the UE or WTRU may be        configured with a UTC of a subset thereof as part of a PRACH        configuration. More specifically, the UE or WTRU may be        configured with separate UTC configuration for different type of        dedicated preambles, random access trigger (e.g. by PDCCH or        RA-SR) and/or PRACH resource indexes. In one or more embodiments        may, the UE or WTRU may determine what UTC may be applicable for        a preamble based on an indication in PDCCH DCI format 1a and/or        in the RAR (e.g. the grant) for an uplink transmission for msg3.        Alternatively, the UE or WTRU may determine the applicable UTC        for the preamble based on the PtRS associated with the received        PDCCH and/or RAR reception;    -   One or more UTCs may apply to a plurality of channels/signals:        The UE or WTRU may use the UTC of the PUSCH channel (e.g.        possibly based on the activation state of the UTC) for the        transmission of a subset of the other channels (e.g. PUCCH) or        transmission types (e.g. SRS); and/or    -   A combination thereof: in one embodiment, a combination may be        provided where the PUCCH may use the UTC configuration of the        PUSCH and a separate UTC for SRS may be configured. In        particular, the above may be applicable to the configuration of        UTC(s) for PUCCH, PRACH and/or SRS transmissions.

The transmission power levels for different physical channels ortransmission types may be dependent on a combination of at least one ofthe following variables: P_(CMAX,c)—the configured maximum UE or WTRUtransmit power for UTC c; M—the bandwidth of the channel; P_(o)— thedesired received power; PL_(c)—the uplink path loss applicable to UTC c;A partial path-loss compensation; A power control adjustment state;and/or a configurable offset.

Given that the UTC for a physical channel or transmission type maychange dynamically, one or more, or each, UTC may have its own set oftransmission power parameters. Furthermore one or more, or each,physical channel (e.g., PUSCH, PUCCH, and PRACH) or transmission type(e.g., SRS) may have its own set of transmission power parameters forone or more, or each, UTC. In one or more embodiments, these sets ofparameters may overlap and reuse the same values for some or one ormore, or all, parameters. To have different sets of parameters mayrequire that one or more, or each, UTC has a distinct value for pathloss. The UE or WTRU may therefore be configured with the transmissionpower level of one or more, or all, the possible transmission points orUTCs as well as specific reference signals for one or more, or each. Thepath loss may be therefore defined as PL_(c)=reference signal power ofc−higher layered filtered RSRP of c, for UTC c.

The RSRP may be calculated from at least one of: PtRS or new (e.g.,contemplated by embodiments) UTC-specific reference signal; CRS; and/orCSI-RS.

Embodiments contemplate that to determine which set of reference symbolsto use to determine the path loss, among other reasons, the UE or WTRUmay be informed via higher layer signaling the link between a UTC andthe appropriate set of reference symbols. Upon selecting a UTC (asdescribed herein), a UE or WTRU may then derive the path loss value.

In one embodiment, the UTC of a physical channel or transmission typemay be configured with multiple PtRS's from which multiple path lossmeasurements may be derived. In this case, a method to select the pathloss used may be one or more of the following: The lowest path lossvalue for any PtRS; The highest path loss value for any PtRS; The linearaverage of path loss values of the set of PtRS's; and/or anypreconfigured path loss value of a specific PtRS; and/or a function ofthe path loss values of the set of PtRS's (e.g. addition of one or more,or all, individual path loss values). In one or more embodiments, PtRSselection can also be used to select a UTC for the purpose of ULtransmission and path loss reference determination.

Furthermore, for the case where the UTC may be configured with multiplePtRS's, other parameters (for example, a desired receive power Po) mayalso be selected similarly (e.g., one of the maximum, minimum, averageor preconfigured selection of desired receive power). The selectionmechanism may be signaled via higher layer RRC signaling and does nothave to be the same for one or more, or all, parameters.

The current power control adjustment state may be composed of either thesum of the previous power control adjustment state plus the most recentcorrection value (also referred to as TPC command), or just the mostrecent correction value (most recent TPC command). In order to enableproper power control adjustment state, the UE or WTRU may perform atleast one of (or any combination thereof): Maintain a TPC command chainper UTC configured; Maintain a TPC command chain per PtRS (linking a TPCcommand chain to a path loss); Maintain a TPC command chain per physicalchannel or transmission type; A combination thereof; for example, oneTPC command chain may be maintained for a set of physical channels (e.g.PUSCH/PUCCH) and a TPC command per UTC may be maintained for anotherchannel or transmission type (e.g. SRS). Alternatively, in someembodiments if an SRS is being transmitted to the UTC that is being usedfor PUSCH/PUCCH the same TPC command as that of PUSCH may be used and anindependent one may be maintained for SRS transmission to other points(e.g. UTC).

An example of when a UE or WTRU may find it useful to maintain multipleTPC command chains may be if a physical channel is configured to usedifferent UTC depending on the transmission type. For example, a PUCCHused for HARQ may use a different UTC than a PUCCH used for schedulingrequests, and may therefore one or more, or each, have its own TPCcommand chain.

A UE or WTRU may determine for which UTC a TPC command may be for by atleast one of: a UTC indication attached to one or more, or all, TPCcommands; the search space from which a DCI may be decoded from; the useof different RNTI (one per UTC) to scramble to CRC of a DCI; thesubframe number when the TPC command may be received; and the downlinktransmission point from which the TPC command may be transmitted.

For the case when a new (e.g., fresh or updated) UTC may be selected foran uplink transmission, the updated power control adjustment state maybe at least one of the following: be reset to a preconfigured level (forexample, 0 dBm). This level may be specific to an UTC, or may bespecific to an uplink physical channel; be modified by a preconfiguredoffset, where the offset may be specific to the new UTC or the previousUTC or be specific to the uplink physical channel; remain unaffectedwith the understanding that future TPC command may properly refine thepower control adjustment state, (e.g. any subsequent TPC command may beadded to the previous accumulated TPC for the channel regardless of theUTC); be scaled such that the over-all transmission power remainsunchanged, despite the new (e.g., fresh or updated) desired receivedpower and path loss for the new (e.g., fresh or updated) UTC; beretrieved from the most recent time that UTC was used. In suchscenarios, the UE or WTRU may (or in some embodiments, perhaps must)save one or more, or all, the most recent power control adjustmentstates for one or more, or all, the channels and for one or more, orall, the UTCs; and/or be reset to the last value used for uplinktransmission to that UTC and/or to that PtRS and/or for that physicalchannel and/or for that transmission type.

In one or more embodiments, a UE or WTRU may be configured with multipleUTC and may autonomously select a UTC for a channel. In order to selectthe UTC for a current transmission on an uplink channel, the UE or WTRUmay use at least one of: the UTC requiring the lowest transmit power. Insuch a case, the transmit power may be determined by using theappropriate set of power setting parameters for that UTC; the UTC may beselected according to any of the mechanisms described herein; the UTCmay be selected by applying a selection mechanism on any of theparameters. The possible selection mechanisms include: maximum, minimum,a minimum (or maximum) threshold difference over the previously selectedUTC's parameter. For example, the UE or WTRU may choose a UTC byselecting the one which minimizes the path loss. The power setting maythen be determined by applying one or more, or all, parameters thatapply to that UTC. As another example, a UE or WTRU may select a new(e.g., fresh or updated) UTC by ensuring that the difference in nominalpower between the previous UTC and the new (e.g., fresh or updated) UTCbe less than a predetermined threshold. The parameter list may beexpanded to include MCS.

In another embodiment, a new (e.g., contemplated by embodiments) powerlevel offset may be used for the case where the UTC may be configuredwith multiple PtRS's. This offset may be either positive to ensure thatone or more, or all, intended reception points have a chance at properlydecoding, or it may be negative, if the network determines that withmore reception points cooperating to decode the data, less power may berequired. The offset may be preconfigured via higher layers or may bejointly coded with other TPC commands in PDCCH with DCI format 3/3Awhose CRC may be scrambled with a new (e.g., contemplated byembodiments) RNTI (e.g. such as TPC-COMP-RNTI).

Any power control parameter discussed herein, (such as PCMAX,c), may betied to the subframe when such an UL transmission occurs. For example,there may be subsets of subframes which require different sets of powercontrol parameters. In such scenarios, the UTC for one or more, or each,physical channel or transmission type may remain the same regardless ofthe subframe number. However, some power control parameters may besubframe number dependent. For example, in a subset of subframes, the UEor WTRU may use a set of offset values that may be UTC and/or physicalchannel and/or transmission type dependent, and in another subset ofsubframes, another set of offsets may be used. In one or moreembodiments, the UTC used for one or more, or each, physical channel ortransmission type may depend on the subframe number.

Embodiments contemplate one or more enhancements to SRS power control.The enhancements may be applied to one or more of: 1) one or more, orall, SRS transmission; or 2) aperiodic SRS (in some embodiments perhapsonly aperiodic SRS) (e.g., type 1 SRS trigger), or Periodic SRS (in someembodiments perhaps only periodic SRS) (e.g., type 0 SRS trigger).Furthermore, the enhancements described herein for aperiodic SRS maypossibly be applied when aperiodic SRS may be triggered with one or morespecific values of the SRS request field, and not for other values.

Embodiments contemplate SRS Power Control. Given that a UTC used for SRSmay be different than that used for PUSCH, the setting of the UE or WTRUtransmit power P_(SRS) for SRS transmitted on subframe i for the UTC cwhen there may be no PUSCH transmission on c may be defined by:P _(SRS,c)(i)=min{P _(CMAX,c)(i),10 log₁₀(M _(SRS,c))+P_(O_SRS,c)(j)+α_(c)(j)·PL_(c) +h _(c)(i)} [dBm],where P_(CMAX,c)(i) may be the configured WTRU transmit power insubframe i and UTC c, M_(SRS,c) may be the bandwidth of the SRStransmission, and α_(c) (j) may be a 3-bit parameter provided by higherlayers for UTC c. PL_(c) may be defined per UTC as explained herein andP_(O_SRS,c) (j) may be the desired or target received power for UTC c.This variable j may be used to denote that the desired target receivedpower may depend on whether the SRS may be aperiodic or periodic or forregular SRS or probing SRS, and h_(c) (i) may be the current SRS powercontrol adjustment state for UTC c and may be either the sum of theprevious power control adjustment state h_(c) (i−1) and a TPC commandfor SRS, or just a TPC command for SRS. For aperiodic SRS, the TPCcommand for SRS can be included in the aperiodic SRS trigger. Forperiodic SRS, the TPC command can be either included in PDCCH with DCIformat 0/4 for UTC c or jointly coded with other TPC commands in PDCCHwith DCI format 3/3A whose CRC parity bits may be scrambled withTPC-SRS-RNTI.

For DL CoMP, it may be useful to have one or more, or all, CoMPcooperating set cells receive SRS in order to determine the DL CoMPtransmission points (e.g., SRS used for probing). In such a case, thepower setting used for SRS may be useful to be different than forregular SRS used for dynamic scheduling purposes. Therefore, a UE orWTRU may be configured with at least two types of periodic SRS, one ormore, or each, with its own power setting parameters (e.g., desiredpower, TPC command chain, path loss reference, etc. . . . ). The typesof periodic SRS may be differentiated by at least one of: Desired ortarget received power P_(O_SRS,c)(j); Subframe periodicity; Subframeoffset; Use of frequency hopping (for example, for the SRS intended formany destination points, it may be useful to use frequency hopping inorder to focus the available power onto a narrowband); Differentscrambling; Reference signal sequences may be separated into two sets;one or more, or each, associated with a different type of SRS. The setscan be signaled via higher layer signaling.

The reference point (PtRS) or UTC to use to estimate the PLc in order todetermine the transmission power of a SRS transmission may be determinedaccording to any of the methods described herein. For example, for theSRS configuration used to be sent to one or more, or all, CoMP cell thePtRS or UTC to use for path loss estimation can be determined accordingto one or more of: the point with the highest path loss (e.g., to ensureone or more, or all, cells get the SRS); or the default UTC or thepre-configured UTC to be used for this type of SRS and, for example, thepath loss for a SRS used to be sent (or in some embodiments perhaps usedonly to be sent) to a specific UTC may be determine as described aboveor according to the path loss used for PUSCH transmission if PUSCHtransmission may be performed for that UTC.

In one or more embodiments, the same power setting parameters may beused for the two types of SRS (probing and regular), however, in orderto increase the received power for probing SRS, frequency hopping may beused, while for regular SRS non-frequency hopping may be used.

In one or more embodiments, the same power setting parameters may beused for the two types of SRS, however a new (e.g., contemplated byembodiments) offset may be included which the UE or WTRU may use whensetting the power for the probing type of SRS.

In one or more embodiments, at least one of the power settingsparameters, TPC commands and SRS power control adjustment states foraperiodic SRS may correspond to the parameters, TPC commands and/or SRSpower control adjustment states of PUCCH. Embodiments contemplate thatthe power control adjustment state for SRS may be modified by thereception of a TPC command in a downlink assignment, even though theremay be no SRS transmission.

When aperiodic SRS may be triggered, it may include an IE whichindicates for what type of SRS the trigger may be for. In such a case,the UE or WTRU may use the appropriate power setting parameters for theSRS transmission. Alternatively, in an aperiodic SRS grant, a one timeoffset may be transmitted, which informs the UE or WTRU to modify thepower setting for SRS using this offset for the aperiodic SRS (or insome embodiments perhaps only for the aperiodic SRS) and not for furtherSRS.

In one or more embodiments, different UTC may share a subset ofparameters for different SRS. Furthermore, some parameters linked to aphysical channel or transmission type used by a UTC may be configured ortransmitted by another UTC. In such a case, an indication of UTC forwhich a configuration or parameter may be for may be added to thetransmission of the configuration or parameter. This may ensure that theWTRU knows for which UTC and/or channel and/or transmission type aconfiguration or parameter may be for. One such scenario may be a casewhere a WTRU may be configured for periodic SRS (PSRS) for one UTC andaperiodic SRS (ASRS) for another UTC. An example of this may be wherePSRS may be used to assist in uplink transmission from point (or cell)A, while ASRS may be used to assist downlink transmission from point (orcell) B. In such scenarios, the two SRS may require different powercontrol parameters. For example a WTRU may be indicated by a differentP_(O_SRS,c)(j) (or equivalently, P_(SRS_OFFSET,c) (m)) value for one ormore, or each, UTC. Furthermore, P_(O_SRS,c)(j) (or P_(SRS_OFFSET,c)(m)) may be useful to be dynamically indicated by L1 signaling. Forinstance, the value of the offset (P_(SRS_OFFSET,c)(m)) may be afunction of the value of the SRS request field.

Embodiments contemplate decoupling of TPC commands between aperiodic SRS(ASRS), periodic SRS (PSRS) and PUSCH. The TPC command may be useful tobe kept separate between the ASRS and PSRS and PUSCH, and possiblydepending on the value of the SRS request field used to trigger ASRS. Insuch a case, ASRS and PSRS and PUSCH may maintain their own TPC commandchain. For the case where the ASRS and PSRS TPC command chains may bedecoupled from the PUSCH TPC command chain, enhancements may be requiredto indicate for what UTC (or SRS) a TPC command may be for. One methodmay be to add a new (e.g., contemplated by embodiments) informationelement (IE) to the ASRS trigger which provides a TPC command.Furthermore, this TPC command may be used for ASRS, PSRS, PUSCH or anycombination of these transmission types. To indicate for which point theTPC command may be for, a new (e.g., contemplated by embodiments)bit-field may be included. This bit-field may use a preconfiguredmapping. For example, value 00 may indicate a TPC command for ASRS,values 01 may indicate a TPC command for PSRS, and so on. In one or moreembodiments, on top of indicating what ASRS parameters to use, the SRSRequest Field may be used to indicate for what transmission type the TPCcommand may be used. In one or more embodiments, a new (e.g.,contemplated by embodiments) bit field may be added to the PUSCH TPCcommand which indicates for which combination of transmission types,(ASRS, PSRS or PUSCH) a TPC command may be for. In one or moreembodiments, the TPC field itself may be reinterpreted to indicate botha power control adjustment and an indication of whether the adjustmentapplies to at least one of ASRS, PSRS or PUSCH.

In one or more embodiments, the TPC command may apply to PUSCH (or insome embodiments perhaps only to PUSCH) if the TPC command may bereceived as part of a DCI containing an uplink grant where the SRSrequest field indicates that aperiodic SRS may be not triggered, (e.g.,“No type 1 SRS trigger”). For other values of the SRS request field,PUSCH power may be not adjusted.

In one or more embodiments, the TPC command applies to ASRS (or in someembodiments perhaps only ASRS) if (among other contemplated conditions)the TPC command may be received as part of a DCI containing an uplinkgrant where the SRS request field indicates that aperiodic SRS istriggered, (e.g., value of the field not set to “No type 1 SRStrigger”). For other values of the SRS request field, ASRS power may notbe adjusted.

In one or more embodiments, ASRS triggered with different values of theSRS request field may maintain separate power control adjustment states.In such scenarios, a TPC command received as part of a DCI containing anuplink grant may apply to (or in some embodiments may only apply to) theASRS triggered with the value of the SRS request field in the same DCI.

In one or more embodiments, the TPC command may apply to ASRS (or insome embodiments may only apply to ASRS) if (among other contemplatedconditions) the DCI may be such that the transmission of a transportblock (in uplink) is disabled, such as for instance when I_(MCS) is setto 0 and N_(PRB) is set larger than 1, or when I_(MCS) is set to 28 andN_(PRB) is set to 1. In one or more embodiments may, the TPC commandalso does not apply to PUSCH under the same condition.

In one or more embodiments, a DCI, (e.g., an uplink grant, downlinkassignment, or DCI 3/3A), may be used to indicate TPC commands.Furthermore a linkage between different periods/offsets of the DCI andTPC command for different transmission types, (ASRS, PSRS, PUSCH), orcombination of transmission types, may be preconfigured at the WTRU. Insuch a case, based on the subframe within which it receives a DCI, theWTRU may know or determine what UTC/transmission type the TPC commandmay be for.

In one or more embodiments, the applicability of the TPC command maydepend on the DCI format in which it may be received. For instance, aTPC command received in DCI format 3 may apply to PUSCH only, (or toASRS only, or to PSRS only), while a TPC command received in DCI format4 may apply to ASRS only. In one or more embodiments, the applicabilityof the TPC command may depend on the value of the RNTI used to mask theCRC of the DCI.

In one or more embodiments, one or more, or each, of periodic SRS andmultiple aperiodic SRS, (where one or more, or each, ASRS may be mappedto different SRS Request Field values), may be configured with possiblydifferent UTC. In such a case or even in a case where multipletransmission types may be configured with the same UTC, there may be abe useful to maintain different TPC command loops for one or more, oreach, of the PSRS and the multiple ASRS as well as for PUSCH and PUCCH.In one or more embodiments, combinations of SRS types and PUSCH andPUCCH may use the same TPC command values in their power controlformulas. As an example, the PSRS and/or a subset of ASRS and/or thePUSCH may use the same TPC command values, while another subset of ASRSand PUCCH may use another. In another example, a TPC command included ina downlink assignment, (e.g., DCI Format 1A/1B/1D/1/2A/2B/2C/2), may beused, (cumulatively or not), for one or multiple ASRS power controlformulas, (in another alternative, this TPC command may be a reuse ofthe PUCCH TPC command).

In one or more embodiments, a TPC command included in an uplink grant,(e.g., DCI Format 0/4), may be used for PSRS, PUSCH and one or multipleASRS power control formulas. Furthermore, DCI Format 3/3A may be usedfor any TPC command by using the appropriate CRC parity bit scrambling.In such an example, one or more, or each, of PSRS and multiple ASRS andPUCCH and PUSCH may have its own scrambling RNTI. Therefore, in thisexample, the TPC command transmitted in uplink grants or downlinkassignments may be used by a group of UTCs, (corresponding to some orany pre-configured combination of the PSRS, the multiple ASRS, the PUCCHand the PUSCH), while further refinement for a subset of the UTCs may beachieved by transmitting TPC commands on DCI Format 3. In suchscenarios, for one or more, or each, physical channel or transmissiontype, (PSRS or ASRS), the UE or WTRU may maintain separate power controladjustment states.

In one or more embodiments, TPC commands (or in some embodiments perhapsonly TPC commands) that may be applied to a group of UTCs, (for example,those in DCI formats 0/1/1A/1B/1D/2/2A/2B/2C/4), may be cumulative,while TPC commands used for single UTC, (for example, those in DCIformat 3/3A), may be valid (or in some embodiments may only be valid)for one instance of UL transmission on the UTC. In one or moreembodiments, groups of physical channels or transmission types may beupdated (or in some embodiments perhaps always updated) with the sameTPC command and in such scenarios, the UE or WTRU may maintain separatepower control adjustment states for one or more, or each, group. In oneor more embodiments, the power control loop for which a TPC command isintended may depend on the subframe number within which the TPC commandmay be transmitted. For example, a group of physical channels and/ortransmission types may be configured to receive a TPC command in aspecific DCI Format. In some embodiments, the members of the group maybe further subdivided into subgroups such that when (or in someembodiments perhaps only when) the DCI Format may be transmitted in asubset of subframes, (e.g., configured by higher layers), a subgroup mayapply the TPC command. In such scenarios, one or more, or each, subgroupof physical channels and/or transmission types may be preconfigured byone or more higher layers to be tied to a subset of subframes.

When a group of physical channels and/or transmission types, (PSRS orany of the ASRS), share a TPC command, (whether they share UTC or not),one or more, or each, individual physical channel and/or transmissiontype may also be configured to apply a different offset to the over-allTPC command chain. In one or more embodiments, when a group of physicalchannels and/or transmission types share a TPC command, one or more, oreach, individual may interpret a TPC command codepoint differently. Forexample, one or more, or each, group may be preconfigured, by higherlayer, a mapping between the TPC command value transmitted and the valueto be used within the power control formula. In some embodiments, agroup of physical channels and/or transmission types may be made up of asingle element, for example.

In one or more embodiments, the choice of UTC may depend on the subframenumber. For example, the same physical channel or transmission type maybe tied to a different UTC depending on specific subframes, based onpreconfigured subsets of subframes. The subset of subframes may bedetermined from at least one of, frame number, subframe number, offsetand periodicity. In such a case, a TPC command may be applicable (or insome embodiments perhaps may only be applicable) for physical channelsor transmission types, (e.g., PSRS or multiple ASRS), whose UTCs may beused in the subframe in which the TPC command was transmitted. In one ormore embodiments, if a TPC command may be transmitted in a subframesubset, then (or in some embodiments perhaps only then) UTCs and/orphysical channels and/or transmission types, (PSRS or multiple ASRS),configured to be used for that subset of subframes may use the TPCcommand. In one or more embodiments, a TPC command may be tied to aspecific physical channel and/or transmission type, independent of theUTC. Therefore, regardless of the subframe number, the TPC command maybe valid. In one or more embodiments, TPC commands transmitted in DCIFormat 3 (or in some embodiments perhaps only such TPC commands) may beused for one or more, or all, subframes. In one or more embodiments, anyother TPC command may be valid (or in some embodiments perhaps may onlybe valid) for a subset of subframes.

Multiple SRS for multiple UTC may serve different purposes, (forexample, PSRS may be used for UL scheduling while ASRS may be used forDL set management). Therefore the frequency with which one or more, oreach, SRS may be transmitted may differ. There may therefore be alinkage between the frequency (and/or periodicity) that TPC commands maybe sent for an SRS and the frequency (and/or periodicity) with whichthis SRS may be transmitted by the WTRU. Furthermore, if open-loop powercontrol may be lacking in precision, it may be possible that lowerfrequency (and/or higher periodicity) TPC commands may lead to powercontrol not converging to an appropriate solution. One method foraddressing may be to modify the granularity of the correction value usedin the TPC command chain. For example, one type of SRS (or PUSCH) may bepreconfigured with a specific mapping of TPC command field value andcorrection value. And another type of SRS (or PUSCH) may bepreconfigured with another mapping. In one or more embodiments, this mayallow different SRS for different UTC to have different TPC commandgranularity.

Embodiments contemplate PRACH Power Control. In SIB 2, the random accessparameters may be provided to a UE or WTRU. These may include whichsignal reference to use, (e.g., either CRS, CSI-RS or anotherUTC-dependent reference signal), for path loss calculations as well aswhat resources to use for PRACH. There can be multiple sets of PRACHparameters provided to the UE or WTRU. These parameter sets may includeat least one of the following, for one or more, or each, UTC: PRACHresource; Set of possible preamble sequences; Preamble received targetpower; and/or RA-RNTI.

For example, one set may be for the UE or WTRU to attempt access on aspecific cell, while another set may be to attempt access on multiplecells for CoMP operation. For example, one set of parameters may haveone subset of preambles which indicate to the network the UEs UTC. InSIB2, there may also be an indication for parameter sets that require UEor WTRU to have CoMP capabilities. One set of parameters (possiblylinked to a UTC)) may be considered the fallback parameters/UTC. In oneor more embodiments, the UTC chosen may also be linked to the type ofrandom access (contention based or non-contention based).

For the case where the UTC includes multiple PtRS's, the path loss maybe determined from at least one of: The minimum value of path loss forany PtRS; The maximum value of path loss for any PtRS; The linearaverage of path losses for one or more, or all, PtRS; Any preconfiguredvalue from the set of path losses for one or more, or all, PtRS.

In the Random Access Response (RAR) message, the network may indicate tothe UE or WTRU the CoMP cooperating set. Furthermore, the TPC commandincluded in the RAR message may include the UTC for which it may bevalid.

In the event of a random access attempt failure, the UE or WTRU may usethe fallback UTC and single cell path loss and begin the random accessanew. In one or more embodiments, the UE or WTRU may continue with thesame UTC and ramp the power up accordingly.

Embodiments contemplate one or more techniques of transmitting an uplinkreference signal and initially, maintaining orthogonality with differentfrequency assignments.

One or more embodiments contemplate reducing peak correlation by way ofcyclic shift (CS) compensation. The amount of correlation peak drift maybe found to be a function of the relative locations of RSs in frequencydomain, which may be derived in terms of number of samples as:

${amountofcorrelationpeakdrift} = {{mod}\left( {{{round}\left( {q\frac{\left( {k_{01} - k_{00}} \right)N}{N_{ZC}^{RS}}} \right)},N} \right)}$where k₀₁ and k₀₀ may be the sub-carrier indexes of the startingpositions of the two RSs. q is the Zadoff-Chu generating index definedin 3GPP standard by

${q = {\left\lfloor {\overset{\_}{q} + \frac{1}{2}} \right\rfloor + {v\left( {- 1} \right)}^{\lfloor{2\;\overset{\_}{q}}\rfloor}}},{v = 0},1$${\overset{\_}{q} = \frac{N_{ZC}^{RS}\left( {u + 1} \right)}{31}},{u = 0},1,{\ldots\mspace{14mu} 29}$with ν, and N_(ZC) ^(RS) being the sequence group index, the basesequence index, and the length of the RS sequence respectively. N may bethe size of inverse discrete Fourier transform (IDFT) in the SC-FDMAbaseband generator and in one or more embodiments N may be=2048.

As a solution to mitigate the peak correlation issue, among otherreasons, the drift of the correlation peak may be pre-compensated byapplying an offset value on top of the planned CS setting, given thatthe UE or WTRU may be scheduled according to a specific resource block(RB) allocation. In particular, an additional offset value, denoted byn_(PRE), may be added to the cyclic shift calculation. For example, forphysical uplink shared channel (PUSCH) DMRS reference signal generation,the cyclic shift may be calculated as follows:

$\alpha_{\lambda} = \frac{2\pi\; n_{{cs},\lambda}}{12}$n_(cs, λ) = (n_(DMRS)⁽¹⁾ + n_(DMRS, λ)⁽²⁾ + n_(PN)(n_(s)) + n_(PRE))mod  12where n_(DMRS) ⁽¹⁾, n_(DMRS,λ) ⁽²⁾, n_(PN)(n_(s)) may be respectivelythe UE or WTRU-specific, layer-specific, and CS hopping CS variablesdefined in 3GPP TS 36.211, V10.x.x, “E-UTRA, Physical channels andmodulation”, which is herein incorporated by reference as if fully setforth herein.

As an exemplary embodiment, the pre-compensation offset variable n_(PRE)may be calculated in the reverse direction of the correlation peakdrift:

$n_{PRE} = \frac{12 \times {{mod}\left( {{{round}\left( {q\frac{\left( {k_{01} - k_{00}} \right)N}{N_{ZC}^{RS}}} \right)},N} \right)}}{N}$For other types of reference signal generation, such as DMRS for PUCCHor SRS, same concept of the CS pre-compensation can be applied where theequations may be presented with some differences.

In a first implementation of the CS pre-compensation method, UE or WTRUmay autonomously perform the CS compensation without involvement of thenetwork operation. The UE or WTRU has direct access to the values ofk₀₁, N_(ZC) ^(RS), and q already from the scheduling grant sent bynetwork. But the starting position of the reference RS, k₀₀, may not begenerally available to the UE or WTRU. In one or more embodiments, oneor more, or all, the WTRUs that may be jointly scheduled in MU-MIMOoperation may be configured with a common k₀₀ value that may bepre-defined or configured by network via higher layer. Upon receivingone or more, or each, uplink grant via uplink related downlink controlinformation (DCI), UE or WTRU may perform the CS compensation on pertransmission time interval (TTI) basis, or for a longer period.Alternatively, additional dynamic signaling mechanism may be introducedto inform the UE or WTRU of the k₀₀ value used by the other UEs underco-scheduling. In one or more embodiments, the k₀₀ value may be signaledas part of an uplink transmission context, (corresponding for instanceto properties of a certain potential destination point), allowing thenetwork to indicate one of multiple k₀₀ values from the indicated uplinktransmission context.

In a second implementation of the CS pre-compensation method, CScompensation may be performed at the network side. In one or moreembodiments, the network scheduler may have all the necessary or usefulinformation available for one or more, or each, UE or WTRU under theco-scheduling. Therefore, may calculate the CS compensation according tothe scheduling decision it makes and pre-modify the Cyclic Shift Fieldin the uplink-related DCI that may be sent to UE or WTRU on one or more,or each, uplink grant. As an example, the Cyclic Shift Field may bemodified in such a way as illustrated in FIG. 8, where the bits inCyclic Shift Field may be modified by offsetting the entry pointer tothe given table in terms of n_(PRE). In some embodiments, the wraparound may be performed when hitting the end of the table.

Alternatively, if additional dynamic signaling mechanism is introducedfor dynamic configuration of CS, among other conditions, the CScompensation may be applied by directly modifying the CS signaling.

At least one aspect of the usefulness of the contemplated CScompensation techniques may be that the current techniques of generatingthe reference signals, such as grouping of the base sequences andconfiguration of various levels of the hopping schemes, may not beuseful to change, which may help to minimize the standardization impactand may make it easier to be backward compatible to legacy WTRUs.

Embodiments contemplate reducing peak correlation by way of furtherrandomization. In defining the reference signals for uplinktransmission, the Zadoff-Chu sequence is used for the base sequencegeneration:

${{X_{q}(m)} = {e - {q\frac{j\;\pi\;{m\left( {M = 1} \right)}}{N_{ZC}^{RS}}}}},\mspace{31mu}{0 \leq M \leq {N_{ZC}^{RS} - 1}}$where q is the root index that may serve as a key parameter to definedifferent base sequences. The length N_(ZC) ^(RS) may be chosen as thelargest prime number as compared to the length of the reference signal,denoted by M_(SC) ^(RS). The Zadof-Chu sequence of length N_(ZC) ^(RS)may be cyclic and may be extended to a base sequence of length M_(SC)^(RS).

The set of available base sequences may include 30 base sequence groupslabeled by u,u=0, 1, 2, . . . , 29, for example. One or more, or each,group may have a set of base sequences of different sizes of M_(SC)^(RS) and for M_(SC) ^(RS)≥72 there may be two base sequences assignedwith sequence label ν,ν=0,1. The relation of the group and sequencelabels to the root index is defined in current 3GPP standard by:

$q = {\left\lfloor {\overset{\_}{q} + \frac{1}{2}} \right\rfloor + {v\left( {- 1} \right)}^{\lfloor{2\;\overset{\_}{q}}\rfloor}}$$\overset{\_}{q} = \frac{N_{ZC}^{RS}\left( {u + 1} \right)}{31}$When the group hopping may be performed, the group number u may varywith the slot number n_(s) according to a group hopping patternf_(gh)(n_(s)):u=(f _(gh)(n _(s))+f _(ss))mod 30where f_(ss) may be a cell-specific sequence-shift parameter configuredby higher layer.

For one or more, or all, base sequences within a base sequence group, itmay be seen that they share a common hopping pattern. Thus for unpairedBW allocation, reference signals being used may (or in some embodiments,may always) have a fixed pair relation regardless of how the hoppingpattern varies. Since the poor peak cross-correlation may appear rarelyand among some pairs of reference signals of unequal lengths (or in someembodiments perhaps only such pairs), it may be useful to performfurther hopping over the reference signals of different sizes. In otherwords, another layer of hopping is contemplated that may be RS lengthdependent. As an example, the group number u may be defined in such away:u=(f _(gh)(n _(s))+f _(ss) +f _(lh)(n _(s) ,M _(SC) ^(RS)))mod 30where f_(lh)(n_(s),M_(SC) ^(RS)) may be the RS length hopping patterncontemplated herein, which may be a function of the RS length M_(SC)^(RS). Further, the RS length hopping pattern may be defined by:

$f_{lh}\left( {n_{s},{M_{SC}^{RS} = \left\{ \begin{matrix}0 & {ifRSlengthhoppingisdisabled} \\{\sum\limits_{i = 0}^{7}\;{\left( {{c\left( {{8\; n_{s}} + i} \right)}2^{i}} \right){mod}{\mspace{11mu}\;}30}} & {ifRSlenghthoppingisenabled}\end{matrix} \right.}} \right.$which may be initialed with a RS length dependent value, for instance,c_(init)=M_(SC) ^(RS), where c(i) may be a pseudo-random sequencegenerating function.

As another example, the RS length dependent hopping may be combined intothe group hopping pattern. In particular, the group hopping pattern maybe made RS length dependent:

u = (f_(gh)(n_(s), M_(SC)^(RS)) + f_(ss))mod  30${f_{gh}\left( {n_{s},M_{SC}^{RS}} \right)} = \left\{ \frac{0\mspace{256mu}{if}\mspace{14mu}{RS}{\mspace{11mu}\;}{length}\mspace{14mu}{hopping}\mspace{14mu}{is}\mspace{14mu}{disabled}}{\sum\limits_{i = 0}^{7}\;{\left( {{c\left( {{8\; n_{s}} + i} \right)}2^{i}} \right){mod}{\mspace{11mu}\;}30\mspace{14mu}{if}\mspace{14mu}{RS}\mspace{14mu}{length}{\;\mspace{11mu}}{hopping}\mspace{14mu}{is}\mspace{14mu}{enabled}}} \right.$which may be initialized by a RS length depend value, for instance:

$c_{init} = {\left\lfloor {\frac{N_{ID}^{cell}}{30} + M_{SC}^{RS}} \right\rfloor.}$Alternatively, if the group hopping is made non-cell specific, theinitial value may be defined by

$c_{init} = \left\lfloor {\frac{GroupHoppingConfig}{30} + M_{SC}^{RS}} \right\rfloor$where GroupHoppingConfig may be a parameter that may be configured byhigher layer, or updated dynamically.

Embodiments contemplate one or more CS hopping enhancements. Thefollowing paragraphs describe contemplated techniques to enhance the useof CS hopping by a UE or WTRU in a deployment with multiple potentialdestination points.

The DM-RS transmitted in a slot n_(s) for a transmission layer λ may bea function of a cyclic shift α_(λ) according to α_(λ)=2πn_(cs,λ)/12where n_(cs,λ) may be a cyclic shift index. The cyclic shift index maybe calculated according to the following formula:n _(cs,λ)=(n _(DMRS) ⁽¹⁾ +n _(DMRS,λ) ⁽²⁾ +n _(PN)(n _(s)))mod 12where at least one of n_(DMRS) ⁽¹⁾ and n_(DMRS,λ) ⁽²⁾ may be a parameterassociated to a UTC. The values of these parameters may be obtained fromhigher layers or may be obtained from a dynamic selection method, suchas from the value of a cyclic shift field (CSF) in uplink-relateddownlink control signaling. The quantity n_(PN)(n_(s)) may be referredto as “cyclic shift (CS) hopping sequence”. It may be a function of theslot number n_(s) that may be derived from a pseudo-random sequence c(i)according to the same relationship as in current systems. Suchpseudo-random sequence may be initialized at the beginning of one ormore, or each, radio frame with a value c_(init) which may be referredto as “initial value for CS hopping”. The value of the cyclic shifthopping sequence initiator c_(init) may be a dependent on the UTC andobtained using at least one of several contemplated techniques describedherein. When a UTC also includes power control parameters enablingreception of the uplink signal at the proper level at a certainreception point, such as the identity of a point-specific referencesignal and/or point-specific power control parameters, embodiments thatmay enable the utilization of a UTC-specific value of c_(init) mayensure that the reference signal may be received at the proper level forthe point for which the structure of the reference signal may be optimalfor the purpose of MU-MIMO combining.

In one or more embodiments, the initial value of the pseudo-randomgenerator used for CS hopping may be decoupled from f_(ss) ^(PUSCH) andmay still be made cell-specific, for instance:

$c_{init} = {{\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor 2^{5}} + {\left( N_{ID}^{cell} \right){mod}\mspace{14mu} 30}}$where N^(cell) _(ID) may correspond to the physical cell identity or toan identity associated to a UTC. In one or more embodiments, the CShopping may be independently configured via c_(init)=Δ_(csh). Incombining the two contemplated techniques, the CS hopping pattern mayalso be initialized by

$c_{init} = {{\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor 2^{5}} + {\left( N_{ID}^{cell} \right){mod}\mspace{14mu} 30} + \Delta_{csh}}$

In one or more embodiments, the UE or WTRU-specific adjustment may bedynamically assigned in the most recent uplink-related DCI (or in theuplink-related DCI to which the current UL transmission may be related).In one or more embodiments, the UE or WTRU-specific adjustment Δ_(csh)may be derived implicitly at the UE or WTRU. One possible implicitderivation may depend on the current base sequence group.

In one or more embodiments, the implicit derivation may be a function ofthe current base sequence group as well as the previous base sequencegroup.

In a one or more embodiments, the additional randomization may beperformed over DMRS of different lengths, similar to the conceptdescribed herein. An exemplary realization may be to have the CS hoppingpattern defined by:

${n_{PN}\left( {n_{s},M_{SC}^{RS}} \right)} = {\sum\limits_{i = 0}^{7}\;{{c\left( {{8\; N_{symb}^{UL}n_{s}} + i} \right)}2^{i}}}$which may be initialized in terms of M_(SC) ^(RS) as well, for instance:

$c_{init} = {{\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor 2^{5}} + {\left( {N_{ID}^{cell} + M_{SC}^{RS}} \right){mod}\mspace{14mu} 30}}$or alternatively if UE or WTRU-specific adjustment may be used

$c_{init} = {{\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor 2^{5}} + {\left( {N_{ID}^{cell} + M_{SC}^{RS}} \right){mod}\mspace{14mu} 30} + {\Delta_{csh}.}}$

In one or more embodiments, the CS may be obtained using the sameformulas as in the current system,

$c_{init} = {{\left\lfloor \frac{N_{ID}^{cell}}{30} \right\rfloor \cdot 2^{5}} + f_{ss}^{PUSCH}}$but certain parameters may be replaced with UE or

WTRU-specific parameters, and in some embodiments may be provided in anuplink transmission context. The parameters that may be provided in theuplink transmission context may include:

The Cell ID (N^(cell) _(ID)) may be replaced with a UTC-specific value(N^(UTC) _(ID)).

The sequence shift pattern f_(ss) ^(PUSCH) may be replaced with aUTC-specific value f_(ss) ^(PUSCH-UTC). In the latter case, theUTC-specific value f_(ss) ^(PUSCH-UTC) may be provided directly or maybe derived from the UTC-specific cell ID parameter (N^(UTC) _(ID)) and,in some embodiments, perhaps another UTC-specific parameter (Δ^(UTC)_(ss)). These values may or may not be configured independently frompossible other UTC-specific cell ID parameters used in the calculationof other properties of the UTC, such as the base sequence for example.One or more embodiments contemplate that

f_(ss) ^(PUSCH-UTC)=(N_(ID) ^(UTC) mod 30+Δ^(UTC) _(ss))mod 30. In someembodiments, in case the parameter Δ^(UTC) _(ss) may not be present ormay not be defined, this formula could be simplified as follows: f_(ss)^(PUSCH-UTC)=N_(ID) ^(UTC) mod 30. In such cases, the initial value ofthe pseudo-random sequence generator c_(init) can be summarized as:

$c_{init} = {{\left\lfloor \frac{N_{ID}^{UTC}}{30} \right\rfloor \cdot 2^{5}} + {N_{ID}^{UTC}{mod}\mspace{14mu} 30.}}$

Such embodiments may allow the network to schedule the UE or WTRU usinga cyclic shift hopping pattern matching that may be used in adestination point that may be used by another co-scheduled UE or WTRU,minimizing the interference with this co-scheduled UE or WTRU. Thecontemplated techniques allowing the selection of one of multiple UTC's,(described herein), may allow the selection by the network of thedestination point and corresponding co-scheduled UE or WTRU with whichit may be most appropriate to minimize interference, when multiple suchdestination points exist.

In the aforementioned embodiments, the parameters for the determinationof CS hopping may be the same regardless of whether the DM-RS may betransmitted as part of PUCCH or PUSCH. Alternatively, at least oneparameter may be different between PUCCH and PUSCH. In this case,distinct parameters may be utilized by the UE or WTRU as part of a sameUTC for a transmission over PUCCH or PUSCH, or different UTC's may bedefined for transmission over PUCCH or PUSCH.

The following methods may be employed alone or in combination for theselection of an UTC for an UL transmission. In the followingembodiments, a downlink control signaling may be said to be “applicable”to an uplink transmission if the uplink transmission is triggered bythis signaling. This may include, for instance, DCI (decoded in PDCCH orE-PDCCH) indicating a grant for a PUSCH transmission, a DCI indicatingan aperiodic SRS transmission, a DCI indicating a RACH order, or a DCIindicating a downlink assignment for which HARQ feedback may be usefulto be transmitted over a PUCCH.

For the purpose of determining a UTC to use for a certain uplinktransmission, among other contemplate conditions, the UE or WTRU mayfirst determine a subset of candidate UTCs using at least onecontemplated restriction technique. The UE or WTRU may then select theUTC from the UTCs available in the subset of candidate UTCs. In casethis subset may be empty, the UE or WTRU may use a “default” UTC whichmay be available (or in some embodiments may always be available). Such“default” UTC may correspond to a UTC allowing reception from mostpoints of the cell. For instance, the “default” UTC may use the commonreference signal as the PtRS.

Some example restriction methods are provided in the following. In onemethod, the UE or WTRU may determine that a UTC may be a candidate ifthe path loss estimated from the PtRS may be below a threshold. The pathloss may be estimated as the difference between the transmission powerand the received power (RSRP) in dB units. In one or more embodiments,the UE or WTRU may determine that a UTC may be a candidate if thereceived signal power or quality measured from the PtRS may be above athreshold. In one or more embodiments, the UE or WTRU may determine thata UTC may be not a candidate if connectivity exists for this UTC. In oneor more embodiments, the UE or WTRU may determine that UTC may be not acandidate if an activation state associated to this UTC is deactivated.

The UE or WTRU may determine the UTC based on the type of uplinktransmission, possibly according to a higher-layer indication orconfiguration. In one example, an aperiodic SRS transmission may beconfigured to be transmitted using the transmission parameters of afirst UTC and a periodic SRS transmission may be configured to betransmitted using the transmission parameters of a second UTC. Inanother example, for a first periodic SRS transmission configured totake place with a first period and offset the UE or WTRU may use a firstUTC, while for a second periodic SRS transmission configured to takeplace with a second period and offset the UE or WTRU may use a secondUTC. In another example, the UE or WTRU may use a first UTC for PUSCHtransmissions, and a second UTC for PUCCH transmissions. In anotherexample, the UE or WTRU may use a first UTC for PUSCH transmissionstriggered by a dynamic grant, and a second UTC for PUSCH transmissionstriggered by a semi-persistent scheduling (SPS) grant. In one or moreembodiments, the UE or WTRU may use the second for a PUSCH transmissiontriggered by a dynamic grant if it occurs in place of a SPS grant in thesame subframe. In one or more embodiments, the UE or WTRU may determinethe UTC based on data multiplexed into the transport block or set oftransport blocks carried by the PUSCH transmission. For instance, theUTC may depend on one or more of the logical channel, type of logicalchannel, logical channel group, and/or radio bearer or type of datacontained in a transport block. The logical channel to UTC mapping maybe provided by one or more higher layers to the WTRU. Alternatively, theWTRU may determine the logical channel to UTC mapping based on logicalchannel group (LCG) priorities. In one or more embodiments, for acertain logical channel the UTC selection may further take intoconsideration whether the TB contains user plane data or control planedata, wherein control plane data may correspond to RLC control PDUs(such as status PDUs), or MAC control PDUs, or RRC messages. In someembodiments, this behavior and/or UTC selection may be configured for asubset of logical channels. In case more than one MAC entity or MACinstance is configured, the UE or WTRU may determine the UTC based onthe MAC entity or MAC instance providing the set of transport blockscarried by the PUSCH transmission.

The UE or WTRU may determine the UTC based on the received downlinkcontrol signaling applicable to the uplink transmission. In one method,in case of a PUSCH transmission, the downlink control signaling mayinclude a field indicating the UTC for the PUSCH transmission.

For example, the field may include a Cyclic Shift Field (CSF) in anuplink-related downlink control signaling, where the interpretation ofthe field may be modified compared to that in existing systems. One ormore, or each, value of the CSF may indicate the use of a specific UTC,or the use of at least one parameter associated to the UTC, possiblyalong with the use of other parameters such as an orthogonal cover code(OCC) or a cyclic shift index for one or more, or each, transmissionlayer n_(DMRS,λ) ⁽²⁾. For instance, a value of the CSF may indicate atleast one of: a parameter specific to a UTC, such as an UTC index, or aUTC-specific parameter used in place of a cell identity; at least oneparameter used to determine at least one of a base sequence group numberu and a base sequence number v for one or more, or each, slot n_(s). Theat least one parameter may be associated to a UTC or be common to one ormore, or all, UTC's. For instance, the at least one parameter mayinclude a UTC-specific parameter used in place of a cell identity(N^(UTC) _(ID)) and possibly a UTC-specific parameter (Δ^(UTC) _(ss))used in place of a cell-specific Δ_(ss), for the purpose of calculatingthe base sequence parameters; at least one parameter used to determinean initial value for CS hopping c_(init), such as a UTC-specific value(Δ_(csh) or c_(init) ^(CSH_UTC)) or an UTC-specific identity (N^(UTC)_(ID)) used for the purpose of calculating the initial value for CShopping, or a UTC-specific parameter Δ^(UTC) _(ss) used for the purposeof calculating the initial value for CS hopping; or at least oneparameter used to determine the resource blocks that may be used forPUSCH in one subframe, (or equivalently, which RBs may be used for PUCCHin one subframe). The at least one parameter may be associated to a UTCor be common to one or more, or all, UTC's. For example, the at leastone parameter may include a UTC-specific parameter forpusch-HoppingOffset as well as n-SB and hoppingMode which may be used bythe WTRU to determine the RBs within which PUSCH may be located.

FIG. 9 shows an example of possible modified mapping for the CSF, wherein addition to the cyclic shift index n_(DMRS,λ) ⁽²⁾ and the orthogonalcover code [w^((λ))(0) w^((λ))(1)] for one or more, or each,transmission layer λ, an initial value of CS hopping may be indicatedfor one or more, or each, codepoint. One or more embodiments contemplatethat in place of directly indicating an initial value of CS hopping foreach codepoint (in the last column), a UTC-specific parameter Δ^(UTC)_(ss) can be indicated that may be used for the purpose of calculatingthis initial value of CS hopping, according to one or more previouslydescribed embodiments, e.g.

$c_{init} = {{\left\lfloor \frac{N_{ID}^{UTC}}{30} \right\rfloor \cdot 2^{5}} + {N_{ID}^{UTC}{mod}\mspace{14mu} 30.}}$

In case the CSF may be interpreted as per the above, the UE or WTRU maydetermine (in some embodiments perhaps implicitly) a UTC based on theindicated value of the initial value for CS hopping, (or of anotherUTC-specific parameter, in other contemplated techniques), and inferother properties of the uplink transmission based on this UTC. Forinstance, the UE or WTRU may determine that the transmission power maybe calculated based on a first set of UTC-specific parameters in casethe indicated value of the initial value for CS hopping may be a firstvalue, and that the transmission power may be calculated based on asecond set of UTC-specific parameters in case the indicated value may bea second value. The UE or WTRU may interpret the CSF field differentlydepending on a configuration parameter. For instance, the UE or WTRU mayinterpret the CSF field in the same way as in existing systems if it maybe configured with a single UTC, and use FIG. 9 if it may be configuredwith more than one UTC's.

In one or more embodiments, in case of an aperiodic SRS transmission,the field indicating the SRS request may indicate one of a set ofpossible UTCs, along with other characteristics of the aperiodic SRStransmission.

In one or more embodiments, in case of a PUCCH transmission utilized fortransmitting HARQ feedback, an A/N resource indicator may indicate theUTC to use along with other information on the PUCCH resource that maybe utilized (such as the resource index or another property of the PUCCHtransmission). For instance, the parameter N_(PUCCH) ⁽¹⁾ used for thedetermination of a resource index may be set to a first value in a firstUTC and to a second value in a second UTC, that may allow the use ofdistinct PUCCH regions between adjacent reception points for betterperformance. In another example, the parameters used for thedetermination of the base sequences of the DM-RS for PUCCH, (such as aparameter replacing a cell identity), may be set to a first set ofvalues in a first UTC and to a second set of values in a second UTC. Inanother example, the parameters used for the determination of the RBsused for PUSCH, (such as pusch-HoppingOffset), may be set to a first setof values in a first UTC and to a second set of values in a second UTC.

In another example, the parameters used for determination of the initialvalue of the CS hopping sequence of the DM-RS for PUCCH, (such as theinitial value itself or a parameter replacing a cell identity), may beset to a first set of values in a first UTC and to a second set ofvalues in a second UTC. In another example, the initial value of thepseudo-random sequence c(i) used for the determination of the cyclicshift term n_(cs) ^(cell)(n_(s),l) for one or more, or each, slot n_(s)and symbol number may be set to a first value in a first UTC and to asecond value in a second UTC. The value in one or more, or each, UTC maycorrespond to a UTC-specific cell identity parameter.

In one or more embodiments, in case of a PRACH transmission triggered bya PDCCH order, among other contemplated conditions, a field in the PDCCHorder may indicate a UTC.

In the above methods, the indication of a UTC may include an index(“destination point index” or “carrier indication field” or “UTC” or“transmission point” if used for this purpose) pointing to one ofseveral sets of parameters configured for one or more, or each, possibleUTC, or group thereof. Alternatively, the indication may include anindication to any other parameter that may uniquely identify the UTC,such as an index to a transmission point or DL reference signaltransmitted from the destination point (e.g. associated to the UTC) andused for power control or timing alignment purposes.

The WTRU may determine (in some embodiments perhaps implicitly) the UTCfor an uplink transmission based on a property of the downlink controlsignaling applicable to the uplink transmission. In one method, the UTCmay be determined based on the search space (or location in thetime-frequency grid) where the PDCCH or E-PDCCH containing theapplicable downlink control information (DCI) may have been decoded. Forinstance, in case DCI for a downlink assignment may be decoded in acommon search space, the UTC for the PUCCH containing the HARQ feedbackfor this assignment may correspond to the UTC that may use a commonreference signal (CRS) of the cell as its point reference signal.

In another example, in case DCI for an uplink grant may be decoded in aUE or WTRU-specific search space, the UTC for the PUSCH may correspondto a UTC that may use another reference signal (e.g. CSI-RS) as itspoint reference signal. In one or more embodiments, the UTC may bedetermined based on the type of physical control channel (PDCCH asdefined in current system, or E-PDCCH based on UE or WTRU-specificreference signal(s)) containing the applicable downlink controlinformation (DCI). For instance, in case the DCI may be decoded from aPDCCH, the UTC for the PUCCH containing the HARQ feedback for thisassignment may correspond to the destination point that may use a commonreference signal (CRS) of the cell as its point reference signal.

In another example, in case the DCI may be decoded from an E-PDCCH, theUTC may correspond to the destination point that may use anotherreference signal as its point reference signal. In one or moreembodiments, the UTC may be determined based on the reference signal orantenna port used for the transmission of the corresponding downlinkcontrol signaling. For instance, in case DCI for a downlink assignmentmay be transmitted over an antenna port corresponding to a commonreference signal, the UTC for the PUCCH containing the HARQ feedback forthis assignment may correspond to the UTC that may use a commonreference signal (CRS) of the cell as its point reference signal. Inanother example, in case DCI for an uplink grant may be transmitted overan antenna port corresponding to a DM-RS reference signal, the UTC forthe PUSCH may correspond to a destination point that may use anotherreference signal (e.g. CSI-RS) as its point reference signal. Therelationship between the antenna port used to transmit the downlinkcontrol signaling and the reference signal (or antenna port) of used aspoint reference signal for the UTC of the uplink transmission may beprovided by one or more higher layers.

In one or more embodiments, the UTC may be determined based on the RNTIused to mask the CRC used in the encoding of the corresponding downlinkcontrol signaling. For instance, in case the CRC used in the encoding ofthe DCI for a downlink assignment may be masked with a first RNTI, theUTC for the PUCCH containing the HARQ feedback for this assignment maycorrespond to the destination point that may use a first point referencesignal. In another example, in case the CRC used in the encoding of theDCI for a downlink assignment may be masked with a second RNTI, the UTCfor the PUCCH containing the HARQ feedback for this assignment maycorrespond to the destination point that may use a second pointreference signal. In another example, in case the CRC used in theencoding of the DCI for an uplink grant is the temporary C-RNTI, the UTCfor the DM-RS used in the corresponding PUSCH transmission maycorrespond to a default UTC, where transmission properties may bederived from the physical cell identity. In one or more embodiments, themapping between RNTI and UTC (or its point reference signal) may beprovided by one or more higher layers. In another example, in case theCRC used in the encoding of the DCI for an uplink grant may be maskedwith a first RNTI, the UTC for the PUSCH transmission and associatedDM-RS, (including, for instance, the parameters used to generate thebase sequence of DM-RS), may correspond to a first UTC. In case the CRCused in the encoding of the DCI may be masked with a second RNTI, theUTC for the PUSCH transmission and associated DM-RS may correspond to asecond UTC.

In one or more embodiments, the UTC may be determined based on the DCIformat used. Based on a transmission mode or a configuration mode, adirect DCI format to UTC mapping may be specified. When configured inthis mode, if a DCI format, for example DCI format 5 may be received theUE or WTRU may use the corresponding configured UTC for UL transmission,otherwise if the UE or WTRU receives a different DCI format, it may usea default or the associated UTC.

In one or more embodiments, the UTC, or at least one parameter tied tothe UTC, (for example PUSCH hopping offset), may be determined based onthe lowest CCE index used to construct the PDCCH used for transmissionof the corresponding DCI assignment.

The UE or WTRU may determine (in some embodiments perhaps implicitly)the UTC based on measurements performed for at least one referencesignal associated to at least one UTC. The reference signal used toperform measurements may correspond to at least one of the referencesignals herein, such as the point reference signal of the UTC. The typesof measurements that may be used, for a given reference signal of a UTC,may include at least one of: Received signal power (e.g. similar toRSRP); Received signal quality (e.g. similar to RSRQ); Path loss,estimated as the difference (in dB units) between the transmitted powerand the received power, where the transmitted power may be provided aspart of the configuration; Alternatively, path gain which may be thenegative of path loss in dB units; and/or Channel quality indication.

In one or more embodiments, the UTC may be selected so as to reach (orin some embodiments perhaps only reach) one or a subset of the closestreception points. Such UTC may be selected using at least one of thefollowing criteria: UTC for which path loss of the associated referencesignal may be the smallest (or for which path gain may be the largest);UTC for which received signal power (or received signal quality, orchannel quality indication) of the associated reference signal may bethe largest; and/or UTC for which the transmitted power determined bythe transmit power control context for this UTC may be the smallest.

In one or more embodiments, the UTC may be selected so as to reach alarger set of reception points. Such UTC may be selected using at leastone of the following criteria: UTC for which path loss of the associatedreference signal may be the largest (or for which path gain may be thesmallest); UTC for which received signal power (or received signalquality, or channel quality indication) of the associated referencesignal may be the smallest; and/or UTC for which the transmitted powerdetermined by the transmit power control context for this UTC may be thelargest.

The UE or WTRU may determine that one of a plurality of the abovecriteria may be used for the selection of the UTC based on at least oneof the following:

-   -   The type of uplink transmission (channel or signal). For        instance, the UTC with the largest power may be selected in case        of a periodic SRS transmissions, according to a higher-layer        indication applicable to the type of uplink transmission. For        instance, a certain aperiodic SRS transmission may be configured        to use the UTC with the largest power;    -   Based on downlink control information applicable to the uplink        transmission. For instance, a field in the DCI indicating an        uplink grant may indicate whether to use the UTC with the        largest or the smallest power; and/or    -   Based on subframe timing.

In one or more embodiments, the UE or WTRU may determine (in someembodiments perhaps implicitly) the UTC based on the timing of thesubframe where the uplink transmission takes place, or the timing of thesubframe where the downlink control information may be applicable to theuplink transmission. The timing may be defined using at least one of aframe number, subframe number, periodicity and offset. One applicationof this method may be for the case where a UE or WTRU may highlyinterfere with a node that it cannot select as a reception point. Insuch a case, the network may configure the UE or WTRU with a subset ofsubframes for which it may use regular uplink transmission and anothersubset of subframes for which it may use limited transmission. Thelimitation on transmission may be a reduction in transmission power forone or more, or all, physical channels and/or transmission types. Or itmay be a reduction in applicable CS hopping and/or PUSCH hopping. Inanother example, the UE or WTRU may determine the UTC to use in a givensubframe based on one or more of a specific set of possible subframeconfigurations, where a subframe configuration may define for some oreach subframe which MAC instance(s) or MAC entity or entities) cantransmit over PUSCH, or alternatively for some or each MAC instance orMAC entity the subset of subframes may be available for transmissionover PUSCH.

In one example method, the UTC used for uplink transmissions occurringin the subset of subframes whose frame number (Nf) and subframe number(Ns) satisfy (10×Nf+Ns) mod T1=O1, where T1 and O1 may be parametersthat may be provided by one or more higher layers, may be determined tocorrespond to the UTC that may use a common reference signal (CRS) ofthe cell as its point reference signal. In another example method, theUTC used for uplink transmissions may be determined based on a bitmapprovided by higher layers, where one or more, or each, position of thebitmap corresponds to a certain subframe and the value of the bitmapindicates the UTC to use.

In another example method, the initial value for CS hopping and/or PUSCHhopping offset may be determined to be a first value, (possiblycorresponding to a first UTC), for even-numbered subframes, and a secondvalue, (possibly corresponding to a second UTC), for odd-numberedsubframes. The two values may be provided by higher layers. Thetransmission power may also be determined based on parameters associatedto the respective corresponding UTC. For example, in one subset ofsubframes, a UE or WTRU may be configured with one set of UTCs one ormore, or each, configured with a specific transmission power offset.While in another subset of subframes, the UE or WTRU may be configuredwith another set of UTCs, which may be a near replica of the first setof UTCs, save for some differences in some parameters, such as adifferent transmission power offset.

In one or more embodiments, the UE or WTRU may determine (in someembodiments perhaps implicitly) the UTC based on the type of subframewhere the uplink transmission takes place, where the type of a subframemay be one of at least a specific subset of “MBSFN” subframes, an“almost blank” subframe, or a “normal” subframe. For instance, the UTCused for uplink transmissions taking place during a first subset ofMBSFN subframes may be determined to correspond to the UTC that may usea first point reference signal, while the UTC used for uplinktransmissions taking place during normal subframe may be determined tocorrespond to the UTC that may use a common reference signal as itspoint reference signal, or to a default UTC.

The UE or WTRU may determine the UTC for an uplink transmission based ona property of this uplink transmission which may have been signaleddynamically in the grant, or configured semi-statically. For instance,the UTC used for a PUSCH transmission may be selected based on theresource block assignment or the hopping offset for this PUSCHtransmission. For instance, it may be a function of the startingresource block or the number of resource blocks or the number ofsubbands or the hopping offset. In another example, the UTC may beselected based on the modulation and coding scheme used for the PUSCHtransmission.

In another example, the UTC used for a PUCCH transmission may beselected based on the physical resource block (PRB) in which the PUCCHtransmission takes place. For instance, the UTC used for a PUCCHtransmission may be set to a first UTC when the PRB belongs to a firstset of PRB's, and to a second UTC when the PRB belongs to a second setof PRB's. Thus, for instance, at least one of the physical cellidentities, and power control parameters and variables, (e.g. referencesignal used for path loss estimation, power control adjustment state),may be selected based on the PRB used for the PUCCH.

In another example, the UTC used for a PUCCH transmission may beselected based on a specific set of uplink transmission properties ofPUCCH as indicated by a PUCCH resource index for a certain PUCCH format.For instance, the UTC used for a PUCCH transmission may be set to afirst UTC when the resource index may be within a first range (or set)of values, and to a second UTC when the resource index may be within asecond range (or set) of values.

The UE or WTRU may determine the UTC for an uplink transmissioncontaining HARQ feedback for at least one downlink transmission on PDSCHbased on a property of this downlink transmission. The uplinktransmission may include at least one of PUCCH or PUSCH containing HARQfeedback. The property of the PDSCH transmission may include at leastone of: Transmission mode (for one or more, or each, transmission);Antenna port or type of reference signal used for PDSCH transmission;and/or Carrier frequency of the PDSCH transmission (or carrier index orcell index).

For instance, the UE or WTRU may use a UTC corresponding to a firstpoint reference signal to transmit A/N feedback (over PUCCH or PUSCH) ifat least one PDSCH transmission was received using an antenna portbetween 7 and 15, and use a UTC for which the point reference signalcorresponds to a common reference signal otherwise.

The UE or WTRU may determine the UTC to use for an uplink transmissionbased on the latest received indication of which UTC to use. Suchindication may have been received from physical, MAC or RRC signaling.

For example, the UE or WTRU may determine the UTC based on the receptionof digital control information on PDCCH, where at least one field of thedigital control information indicates a UTC to use until anotherindication may be provided. In another example method, the UE or WTRUmay determine the UTC based on the reception of a MAC control element,where at least one field of the MAC CE indicates a UTC to use untilanother indication may be provided.

In another example method, the UE or WTRU may determine the UTC based onthe latest received Timing advance command (e.g. the UTC for which thelatest TAC may be applicable to). The UE or WTRU may select the UTC forsubsequent transmissions as a function of the reception of a TAC. In oneor more embodiments, once the UE or WTRU may have determined to what UTCthe received TAC may be applicable to, the UE or WTRU may select theconcerned UTC for subsequent transmissions for the concerned channel,transmission type and/or serving cell or groups thereof.

For example, the UE or WTRU may transmit a SRS for a concerned servingcell (either from a periodic configuration or from an aperiodicrequest), and subsequently receive a MAC TAC CE for the concernedserving cell; the MAC TAC CE may include an indication of a UTC to whichthe TAC applies, and the UE or WTRU may use this UTC for subsequenttransmission in the serving cell such as for PUSCH transmissions.

The UE or WTRU may select a UTC that may be in an activated state (or insome embodiments perhaps only for a serving cell that may be also inactivated state). If one UTC (or in some embodiments perhaps only oneUTC) may be in the activated state at the same time for a given servingcell, among other contemplated conditions, the UE or WTRU may select theactivated UTC. Otherwise, if multiple UTC may be activated at the sametime for a given serving cell, the UE or WTRU may additionally apply anyof the methods described herein to select the UTC to perform the uplinktransmission.

A UTC configuration for PRACH may include at least one of the followingparameters: The initial transmit powerpreambleInitialReceivedTargetPower; The power ramping function and/orfactor powerRampingStep; The maximum number of preamble transmissionpreambleTransMax; The transmit power for the cell e.g. Pcmax,c (anddeltaPreambleMsg3); The preamble format based offset DELTA_PREAMBLE; Setof PRACH Resources (e.g. prach-ConfigIndex); Group of random accesspreambles, set of available preamble per group (e.g.sizeOfRA-PreamblesGroupA, numberOfRA-Preambles); If preamble group Bexists, messagePowerOffsetGroupB and messageSizeGroupA; The RA Responsewindow size; The maximum number of Msg3 HARQ transmissions; and/or Thecontention resolution timer.

For example, the UE or WTRU may perform a preamble transmission on theresources of a serving cell by first selecting a UTC according to one ormore embodiments described above or below. In one or more embodiments,the UE or WTRU may select a UTC and/or how to perform the transmissionof a preamble as a function of one or more of the following:

-   -   The type of preamble transmission, e.g. whether the preamble        transmission may be for a contention-based random access (CBRA),        a contention-free random access (CFRA), for initial access to a        cell upon handover, for connection re-establishment, for a        scheduling request (RA-SR) or for gaining uplink timing        alignment; For example, the UE or WTRU may select a UTC that        corresponds to a default UTC of the concerned serving cell (e.g.        a UTC corresponding to a transmission to a macro cell) if the        preamble transmission corresponds to a CBRA, or alternatively,        upon preamble transmission for the initial access to a cell        during a handover procedure, or as a further alternative, upon        preamble transmission during a RRC connection re-establishment        procedure. Alternatively, upon preamble transmission triggered        by a scheduling request e.g., RA-SR. For example, the UE or WTRU        may select a UTC that corresponds to a UTC for which the UE or        WTRU does not have a valid uplink timing alignment (e.g.        UTC-specific TAT may be expired), or as an alternative, for a        preamble transmission for a SCell (or in some embodiments        perhaps only for a preamble transmission for a SCell);    -   The trigger that initiated the transmission of a preamble, e.g.        whether it may be network-initiated or UE or WTRU-initiated; For        example, the UE or WTRU may select a UTC that corresponds to a        default UTC of the concerned serving cell (e.g. a UTC        corresponding to a transmission to a macro cell) if the preamble        transmission may be autonomously initiated by the UE or WTRU        e.g. corresponds to a RA-SR. For example, the UE or WTRU may        select a UTC that corresponds to the currently active UTC for        the concerned cell if the preamble transmission may be triggered        by the reception of a PDCCH order (e.g. DCI format 1A) to        perform a preamble transmission and/or a random access        procedure. In one or more embodiments, this may be performed if        (or in some embodiments perhaps only if) the PDCCH order        indicates a preamble transmission on Scell, or in a further        alternative, if (or in some embodiments perhaps only if) the        preamble transmission may be for gaining timing advance, among        other contemplated conditions;    -   The type of serving cell for which a preamble may be        transmitted, e.g. whether the preamble transmission corresponds        to a PCell or to a SCell of the UE or WTRU's configuration. For        example, the UE or WTRU may select a UTC that corresponds to a        default UTC of the concerned serving cell (e.g. a UTC        corresponding to a transmission to a macro cell) if the preamble        transmission may be for a PCell. For example, the UE or WTRU may        select a UTC that corresponds to the currently active UTC for        the concerned cell if the preamble transmission may be for a        SCell;    -   An explicit indication that may be received inside control        signaling e.g. in a PDCCH order such as a DCI format 1A. For        example, the UE or WTRU may select the UTC indicated in the        received control signaling, if any such indication may be        present; and/or    -   The currently activated UTC for the concerned cell. For example,        the UE or WTRU may select (or in some embodiments may always        select) the UTC that may be activated for the concerned cell.

The UE or WTRU may then identify the set or parameters applicable toconcerned UTC. For example, for PRACH one or more, or each, UTC may beconfigured with different power-related parameters. For example, thepower ramping function may be a function of the selected UTC. A UTC maythus be configured with a ramping that may be either slower or fasterthan e.g. the power ramping for a default UTC. Similarly, a UTC that maynot be a default UTC for PRACH may be configured with fewerretransmission attempts. The UE or WTRU may then initiate thetransmission of a preamble using the corresponding parameters. The UE orWTRU may select a group of preamble based on Pcmax,c and a PL estimateapplicable to the concerned UTC, e.g. using reference signal that may bespecific to the concerned UTC.

The reference signal used for deriving power control parameters for apreamble transmission may include at least one of the following examplereference signals.

For example, a cell-specific CRS may be used as the default referencesignal (or in some embodiments perhaps always for a given cell or one ormore, or all, cells). For example, the UE or WTRU may determine that theUTC used for preamble transmission may be a UTC configured with a CRS.In one or more embodiments, his may be the default UTC for the concernedcell. For example, the UE or WTRU may determine that the referencesignal used for preamble transmission for a concerned cell may be acell-specific reference signal (or in some embodiments perhaps mayalways be so), independently of the UTC selected for preambletransmission. In this case, the initial transmit power and/or the powerramping parameters may be configured for the selected UTC such that itcompensate for the different power levels between the selected UTC (e.g.a UTC corresponding to a RRH or a pico cell) and a default UTC (e.g. aUTC corresponding to a macro cell). The network may determine whatpreamble reception(s) to consider (e.g. if it successfully decode thepreamble at a plurality of reception points) and respond accordingly,including possibly generating one timing advance command for one ormore, or each, reception point.

Whether or not a cell-specific CRS may be used may be a function of acharacteristic of the preamble transmission (e.g. for CBRA). When CRSmay not be used, a UE or WTRU-specific RS and/or the RS configured forthe UTC may be used; For example, the UE or WTRU may determine that thereference signal used for preamble transmission for a concerned cell maybe a cell-specific reference signal, independently of the UTC selectedfor preamble transmission and/or of the currently active UTC, if thepreamble transmission corresponds to a UE or WTRU-initiated preambletransmission and/or to a CBRA. Otherwise, the UE or WTRU may use thereference signal corresponding to the UTC selected for preambletransmission and/or of the currently active UTC.

Whether or not a cell-specific CRS may be used may be a function of acharacteristic of the selected UTC; For example, if the selected UTCcorresponds to a default UTC, cell-specific CRS may be used.

The RS to use may be explicitly indicated. For example, the UE or WTRUmay receive control signaling with an explicit indication of what UTCand/or reference signal to use for the corresponding preambletransmission, e.g. in a PDCCH order DCI format 1A.

The UE or WTRU may perform an initial preamble transmission on a PRACHresource applicable to the selected UTC for the concerned cell.Subsequently, the UE or WTRU may receive a random access response (RAR)message using a RA-RNTI for decoding control signaling on PDCCH, whichRA-RNTI value may be a function of the selected UTC e.g. such that theRA-RNTI may unambiguously identify what time-frequency resource was usedfor the preamble transmission, and/or also for what UTC (or receptionpoint) the preamble was received. The UE or WTRU may use reception ofcontrol signaling on RA-RNTI to determine to what UTC the RARcorresponds to. More generally, the UE or WTRU may determine (in someembodiments perhaps implicitly) to what UTC a DCI that may besuccessfully decoded with a given RNTI based on the said RNTI, e.g. aUTC may include a RNTI for the purpose of identifying downlink controlsignaling that corresponds to uplink transmissions (e.g. a grant, a TPCor a SRS request).

For example, the UE or WTRU may determine the RA-RNTI for a given UTC byincluding an explicit identifier of the concerned UTC, e.g. such thatRA-RNTI=1+(index of first subframe of PRACH resource for transmittedpreamble)+10*(index of PRACH in frequency domain)+(UTC identity). In oneor more embodiments, the default UTC identity for a given serving cellmay be 0.

If the UE or WTRU reaches the maximum number of preamble transmissionsfor a specific UTC, the UE or WTRU may perform at least one of thefollowing: the UE or WTRU may trigger a RACH failure (e.g. MAC indicatesradio link problems to upper layers) if (or in some embodiments perhapsonly if) the preamble transmissions correspond to a UTC configured asthe default UTC for the concerned cell (e.g. a macro cell); in one ormore embodiments, if (or in some embodiments perhaps only if) theconcerned cell may be a PCell of the UE or WTRU's configuration, the UEor WTRU may deactivate the concerned UTC; and/or the UE or WTRU mayinitiate preamble transmission (e.g. a RACH procedure) on a UTCconfigured as a default UTC for a concerned serving cell (or in one ormore embodiments, perhaps only for the default UTC corresponding to thePCell).

Embodiments recognize that in LTE R8 and later, uplink HARQ processesmay be synchronous. In one or more embodiments, the UE or WTRU mayperform autonomous uplink retransmission for an ongoing HARQ process(e.g. for a HARQ process for which the last feedback received for theprocess may be a HARQ negative acknowledgement, or not feedback wasreceived), until the transmission may be either successful and/or untilthe HARQ process may be stopped (e.g. by the reception of a HARQacknowledgement). The UE or WTRU may additionally receive a grant for aretransmission for an ongoing HARQ process to adapt a retransmission,e.g. in terms of MCS and/or what PRB(s) may be used for theretransmission.

When the UE or WTRU performs a non-adaptive synchronous HARQretransmission for an ongoing HARQ process, among other conditions, theUE or WTRU may select what UTC to apply for the concerned transmissionaccording to at least one of the following: the UE or WTRU may use thesame UTC as for the initial transmission for the concerned HARQ process;for example, the UE or WTRU may apply (or in some embodiments may alwaysapply) the UTC that it applied for the initial transmission for thisHARQ process; in some embodiments if the previous transmission was aretransmission, and if the retransmission was dynamically scheduled(e.g. it was not a UE or WTRU-autonomous retransmission) such that adifferent UTC was used, the UE or WTRU reverts to the UTC of the initialtransmission for this HARQ process for any subsequent UE orWTRU-autonomous retransmission until a new (e.g., fresh or updated)transmission may be initiated for this HARQ process; The UE or WTRU mayuse the same UTC as for the previous transmission for the concerned HARQprocess; For example, the UE or WTRU applies the UTC that it applied forthe previous transmission for this HARQ process; the implication of thismay be that if the previous transmission was a retransmission, and ifthe retransmission was dynamically scheduled (e.g. it was not a UE orWTRU-autonomous retransmission) such that a different UTC was used, theUE or WTRU may apply a different UTC than that of the initialtransmission for this HARQ process; The UE or WTRU may use the defaultUTC for the concerned serving cell; For example, for any HARQ process,the UE or WTRU may apply the default UTC when it performs a non-adaptiveretransmission; The UE or WTRU may use the currently active UTC for theconcerned serving cell. For example, for any HARQ process, the UE orWTRU may apply the currently active UTC when it performs a non-adaptiveretransmission, if one UTC may be active in a given subframe (or in someembodiment perhaps only if one UTC may be so active), among othercontemplated conditions.

A UE or WTRU may be configured with subsets of subframes where fordifferent subsets it may use different UTCs. One or more embodimentscontemplate that for one or more, or each, subset of subframes and oneor more, or each, UTC, a different PCMAX,c may be configured. In such ascenario, it may be difficult to achieve efficient non-adaptiveretransmission. Therefore, non-adaptive retransmission may be enhancedsuch that it may occur (or on some embodiments perhaps may only occur)in the same subset of subframes as the original transmission. In suchscenarios, the UE or WTRU may maintain (or in some embodiments may needor be useful to maintain) separate HARQ processes based on the subframesubset of the original transmission.

When the UE or WTRU receives control signaling for dynamic scheduling ofa HARQ retransmission for an ongoing HARQ process, the UE or WTRU mayselect what UTC to apply for the concerned transmission according to atleast one of the following: The UE or WTRU may use any of the methodsfor selection of a UTC described in paragraphs above and below; The UEor WTRU may use the same UTC as for the initial transmission for theconcerned HARQ process; For example, unless another UTC selection methodmay be applicable (e.g. the UTC may be explicitly signaled in thecontrol signaling), the UE or WTRU may apply the same UTC as for theinitial transmission for this HARQ process. The UE or WTRU may use thesame UTC as for the previous transmission for the concerned HARQprocess; For example, unless another UTC selection method may beapplicable (e.g. the UTC may be explicitly signaled in the controlsignaling), the UE or WTRU may apply the same UTC as for the previoustransmission for this HARQ process. The UE or WTRU may use the defaultUTC for the concerned serving cell; For example, unless another UTCselection method may be applicable (e.g. the UTC may be explicitlysignaled in the control signaling), the UE or WTRU may apply the defaultUTC when it performs the retransmission; The UE or WTRU may use thecurrently active UTC for the concerned serving cell; For example, unlessanother UTC selection method may be applicable (e.g. the UTC may beexplicitly signaled in the control signaling), the UE or WTRU may applythe currently active UTC when it performs the retransmission if (or insome embodiments perhaps only if) one UTC may be active in a givensubframe, among other contemplated conditions.

The UE or WTRU may receive a Timing Advance Command (TAC) in a MAC CE orin a RAR message during the random access procedure. The UE or WTRU maydetermine to what UTC (e.g. what TA accumulator) the TAC appliesaccording to at least one of the following methods:

Explicitly signaled identifier in the message that contains the TAC(e.g. MAC TAC CE, RAR): The message that contains the TAC includes anidentity of the concerned UTC (and possibly also the concerned servingcell) and/or of the concerned UTC group e.g. in a TA Group; For example,the UE or WTRU may receive a MAC TAC CE on the downlink of any servingcell; the UE or WTRU may determine based on a field (or based on abitmap which bit order may indicate such identity) that contains anidentity to what UTC the TAC may be applicable to.

Explicitly signaled identifier in the control signaling that schedulesthe message with the TAC: The downlink control information thatschedules the TAC may include an identity of the concerned serving cell,UTC (and possibly also the concerned serving cell) and/or of theconcerned UTC group e.g. in a TA Group; For example, the UE or WTRU mayreceive a PDCCH DCI scheduling a PDSCH using a cell identificationfield. The CIF may indicate a serving cell, in which case other methodsmay be used to determine to what UTC the TAC may be applicable to e.g.the activated UTC for the indicated cell. Alternatively, the CIF mayindicate a UTC.

Association between an uplink transmission and the received TAC: Thereceived TAC may be associated to an uplink transmission that waspreviously performed by the UE or WTRU. For example, the UE or WTRU mayreceive a TAC inside a RAR that corresponds to a previous preambletransmission. The UE or WTRU may determine to what preamble transmissionthe RAR corresponds to, and may determine that the TAC may be applicableto the UTC corresponding to the said preamble transmission.Alternatively, a RNTI of the UE or WTRU may be used, e.g. a RA-RNTIwhich value may be a function of the UTC applicable for the transmissionof the preamble. Alternatively, this may be based on the PtRS used whendemodulating the downlink transmission that corresponds to the TAC.

Current activated UTC for the concerned serving cell or TA group: TheTAC may be associated to the UTC that is activated at the time ofreception of the transmission that contains the TAC.

In one or more embodiments, the UTC activated for the serving celland/or TA group explicitly indicated in the message that may contain theTAC (e.g. a MAC TAC CE). In one or more embodiments, for a given servingcell and/or a given group of cells and/or transmission channels e.g.cells and/or PUSCH channels configured with the same UTC and/or TAgroup. In some embodiments, once the UE or WTRU may have determined towhat UTC the received TAC may be applicable to, the UE or WTRU maychange the activation state of the concerned TAC to “activated”. In oneor more embodiments, any other UTC of the concerned channel,transmission type and/or serving cell may be deactivated, if at most oneUTC may be activated at any time for the concerned channel, transmissiontype and/or serving cell. In one or more embodiments, the UE or WTRU mayselect the concerned UTC for subsequent transmissions for the concernedchannel, transmission type and/or serving cell.

The UE or WTRU may trigger and/or initiate the transmission of a powerheadroom report (PHR) according to at least one of the following:

-   -   The path loss estimate for a given UTC changes by more than a        threshold. The UE or WTRU may perform path loss estimation based        on a UTC-specific reference signal. The concerned UTC may be a        default UTC for the concerned serving cell. Alternatively, it        may be a UTC that may be in activated state. The threshold may        be configured for one or more, or each, UTC. Alternatively, it        may be a threshold applicable to a group of UTC, either based on        explicit grouping information received from the network or for        the concerned serving cell. The UE or WTRU may trigger a PHR        report when the corresponding PL estimate changes by a        threshold; and/or    -   Configuration, activation and/or change in activation state for        a given UTC. The UE or WTRU may trigger a PHR report when the        activation state of a UTC changes. In one embodiment, this may        be done upon activation of a UTC. In an alternative embodiment,        this may be done upon activation from explicit signaling        received by the UE or WTRU. In yet a further embodiment, this        may be done upon activation that changes the state from        deactivated to activated.

The UE or WTRU may include at least one of the following in a PHR:

-   -   The UE or WTRU may include a PHR value for one or more, or all,        configured UTC. For example, the UE or WTRU may report a        plurality of PH values, including PH for a configured but        deactivated UTC;    -   The UE or WTRU may include a PHR value for one or more, or all,        activated UTC. For example, the UE or WTRU may report a        plurality of PH values, one for one or more, or each, configured        and activated UTC; and/or    -   The UE or WTRU may include a PHR value for the selected UTC in        the subframe in which it performs an uplink transmission that        includes one or more PHR(s). For example, the UE or WTRU may        report a plurality of PH values, one for one or more, or each,        UTC corresponding to a serving cell for which the UE or WTRU        performs an uplink transmission.

For example, for any of the above and for a UTC for which no uplinktransmission takes place in the subframe in which the UE or WTRUperforms an uplink transmission that includes one or more PHR(s), the UEor WTRU may report a PH value by including a value calculated based onspecific parameters for a transmission in that subframe although atransmission for the corresponding UTC does not take place (e.g. avirtual PHR). Multiple PH values may thus be reported for a givenserving cell configured with a plurality of UTC.

In one or more embodiments, a UE or WTRU may be configured with multiplesubframe subsets. For one or more, or each, subframe subset, the UE orWTRU may be required to use different transmission powers. This mayrequire different subframe subsets to be configured with differentPCMAX,c. In such a method, the UE or WTRU may be configured withdifferent UTC for one or more, or each, subframe subsets. Therefore forone or more, or each, UTC, the UE or WTRU may find it useful to reportPHR based on UTC-specific power control parameters. In one or moreembodiments, the same UTC may be used for a specific physical channeland/or transmission type over one or more, or all, the differentsubframe subsets. In such a case, a UE or WTRU may have multiple powercontrol parameters for one or more, or each, UTC, with one or more, oreach, subframe subset having a pre-configured set of power controlparameters. Therefore, the UE or WTRU may report multiple PHR values forone or more, or each, UTC; with one or more, or each, PHR valuecorresponding to a subframe subset, (and hence a corresponding set oftransmission power parameters). In such a method, the UE or WTRU mayinclude a subframe subset identifier in its PHR report. In one or moreembodiments, a PHR report may be valid for the subset of subframeswithin which it may be transmitted (or in some embodiments perhaps onlyvalid for such a subset). In one or more embodiments, one or more, oreach, subset of subframes may have specific PHR reporting instances tiedto them. These PHR reporting instances may not be in the subset ofsubframes.

The UE or WTRU may associate a UTC with an activation state thatindicates whether the UTC may be activated or deactivated. Theactivation state may be used to select the UTC applicable to a givenuplink transmission. This activation state may be independent from theactivation state of the serving cells, given that a PCell cannot bedeactivated. In one or more embodiments, deactivation of a UTC may thusbe applicable to a PCell configured with a plurality of UTC (or in someembodiments perhaps only applicable to such a PSCell). Alternatively,this state may be applicable to any configured UTC.

The UE or WTRU may receive control signaling that activates the use ofcarrier segments for one of more serving cells of the UE or WTRU'sconfiguration. The control signaling may include at least one of thefollowing: layer 1 signaling; layer 2 signaling; layer 3 signaling; UEor WTRU-autonomous activation.

Layer 1 signaling: The UE or WTRU may receive a DCI format on PDCCH thatindicates activation of a UTC for one or more serving cells. In someembodiments, the indication may be according to at least one of thefollowing: The UE or WTRU successfully decodes the DCI format using aconfigured RNTI, e.g. a UTC-RNTI; The UE or WTRU may determine that aDCI format may be of a certain type and/or includes an explicitindication e.g. a field and/or flag; and/or the UE or WTRU may receive aDCI format that indicates a grant for an uplink transmission (e.g. forPUSCH), a request for SRS transmission, or a TPC that may be applicableto a specific UTC.

The control signaling may activate and/or change the activation statefor the UTC to which said DCI format may be applicable. In one or moreembodiments, the DCI format may include an identity of the UTC to whichthe control signaling applies. Alternatively, the control signaling maybe applied to UTC of a concerned serving cell in sequence. For example,if a serving cell may be configured with two UTC, where a first UTC maybe active and a second UTC may be inactive, the control signaling may atonce deactivate the first UTC and activate the second UTC.

The UE or WTRU may transmit a HARQ ACK feedback to acknowledge thereception of the said DCI interpreted as the activation command. Forexample, for DCI signaling received in subframe n, the UE or WTRU maytransmit HARQ ACK on an uplink channel in subframe n+k, where k mayrepresent a UE or WTRU processing delay e.g., k=4 subframes.

Layer 2 signaling: The UE or WTRU may receive a MAC Control Element (CE)that indicates activation of at least one UTC for one or more servingcell(s) of the UE or WTRU's configuration. In one or more embodiments,the MAC CE may be received on the PDSCH of any serving cell of the UE orWTRU's configuration. In one or more embodiments, the UE or WTRUactivates the UTC corresponding to the serving cell based on an explicitindication (e.g. a bitmap, or a transmissionContextId) included in theMAC CE. Alternatively, the UE or WTRU may activate the UTC correspondingto the serving cell on which PDSCH the MAC CE was received, byactivating the next UTC in a sequence. In one or more embodiments, theMAC CE includes a configuration of the resource allocation to use forthe corresponding UTC.

In another example embodiment, the UE or WTRU may change activationstate based on reception of a TAC. The UE or WTRU may change theactivation state of a UTC as a function of the reception of a TAC. Inone or more embodiments, once the UE or WTRU may have determined to whatUTC the received TAC may be applicable to, the UE or WTRU may change theactivation state of the concerned TAC to “activated”. In one or moreembodiments, any other UTC of the concerned channel, transmission typeand/or serving cell may be deactivated, if at most one UTC may beactivated at any time for the concerned channel, transmission typeand/or serving cell or groups thereof. For example, the UE or WTRU maytransmit a SRS for a concerned serving cell (either from a periodicconfiguration or from an aperiodic request), and subsequently receive aMAC TAC CE for the concerned serving cell; the MAC TAC CE may include anindication of a UTC to which the TAC applies, and the UE or WTRU maychange the activation state of the concerned UTC to “activated”.

Layer 3 signaling: The UE or WTRU may receive a configuration for one ormore UTC (s), upon which the default UTC may be in the activated state.

UE or WTRU-autonomous activation (e.g. implicit): The UE or WTRU maymeasure signal reception quality for a given UTC. In one embodiment,this may be done using RSRP measurements. In an alternative embodiment,this may be done using a UTC-specific reference signal. When the UE orWTRU detects that the corresponding measurement may be above a specificthreshold, the UE or WTRU may activate the concerned UTC. In one or moreembodiments, the threshold may be configured by RRC.

In one or more embodiments, the UE or WTRU may additionally deactivateany other UTC configured for the concerned serving cell, such that asingle UTC may be activated at any given time. In some embodiments, theactivation of the use of a UTC for a given serving cell may be appliedimmediately (e.g. in case of layer 1 signaling) or in one or moreembodiments after a fixed delay of e.g. k subframes (e.g. in case oflayer 2/3 signaling). For example, for layer 2 signaling received atsubframe n, the UE or WTRU may consider the UTC in the activated statefrom subframe n+k, where k may be equal to 8 subframes; alternatively,in the subframe after the transmission of a HARQ ACK for the transportblock in which the MAC CE was received. In one or more embodiments, theUE or WTRU may further delay the start of the use of a UTC for a givenongoing HARQ process until the HARQ process successfully completesand/or until the control signaling received indicates a new (e.g., freshor updated) data transmission (e.g. from the New Data Indicator—NDIfield in the DCI format).

When the UE or WTRU receives control signaling that activates one ormore UTC, the UE or WTRU may consider the first assignment for thecorresponding HARQ buffer subsequent to the subframe in which theactivation state changes as a new (e.g., fresh or updated) transmission,for a HARQ process that corresponds to a serving cell for which the UTCused may be changed. For example, the UE or WTRU may perform any (or atleast part) of the above in the subframe in which the UE or WTRUreceives control signaling. Alternatively, the UE or WTRU may perform atleast part of the above in the subframe in which the UE or WTRU firstmay use the activated UTC (e.g. in the subframe of the activation). Inyet another alternative, the UE or WTRU may perform at least part of theone or more aforementioned embodiments for control signaling thatchanges the activation state of a UTC to the activated state (or in someembodiments perhaps for only such control signaling).

If a UE or WTRU may be configured with a plurality of UTC for a givenserving cell, and if multiple UTC may be activated in a given subframe,the UE or WTRU may perform additional selection process to determinewhat UTC to use for an uplink transmission on the concerned servingcell. The UE or WTRU may additionally consider that a UTC may not beused, if the corresponding SCell may be in the deactivated state. In oneor more embodiments, one or more, or all, UTC configured for a givenSCell may be deactivated when the concerned SCell may be in thedeactivated state.

The UE or WTRU may receive control signaling that deactivates the use ofone or more UTC for a given serving cell of the UE or WTRU'sconfiguration. The control signaling may include at least one of thefollowing: layer 1 signaling; layer 2 signaling; layer 3 signaling.

Layer 1 signaling: The UE or WTRU may receive a DCI format on PDCCH thatindicates deactivation of one or more UTC(s). In some embodiments, theindication may be according to at least one of the following: The UE orWTRU successfully decodes the DCI format using a configured RNTI, e.g. aCS-RNTI; The UE or WTRU may determine that a DCI format may be of acertain type and/or includes an explicit indication e.g. a field and/orflag; The UE or WTRU receives an indication to activate a UTC differentthan the UTC currently activated for the concerned serving cell, and asingle UTC may be in the activated state at any given time.

The control signaling may deactivate and/or change the activation statefor the UTC to which said DCI format may be applicable. In one or moreembodiments, the DCI format may include an identity of the UTC to whichthe control signaling applies. Alternatively, the control signaling maybe applied to UTC of a concerned serving cell in sequence. For example,if a serving cell may be configured with two UTC, where a first UTC maybe inactive and a second UTC may be active, the control signaling may atonce activate the first UTC and deactivate the second UTC.

The UE or WTRU may transmit a HARQ ACK feedback to acknowledge thereception of the said DCI interpreted as the deactivation command. Forexample, for DCI signaling received in subframe n, the UE or WTRU maytransmit HARQ ACK on an uplink channel in subframe n+k, where k mayrepresent a UE or WTRU processing delay e.g., k=4 subframes.

Layer 2 signaling: The UE or WTRU may receive a MAC Control Element (CE)that indicates deactivation of at least one UTC for one or more servingcell(s). In one or more embodiments, the MAC CE may be received on thePDSCH of any serving cell of the UE or WTRU's configuration. In one ormore embodiments, the UE or WTRU deactivates the UTC corresponding tothe serving cell based on an explicit indication (e.g. a bitmap, or atransmissionContextId) included in the MAC CE. Alternatively, the UE orWTRU may deactivate the UTC corresponding to the serving cell on whichPDSCH the MAC CE was received, by activating the next UTC in a sequence.In one or more embodiments, the MAC CE may include a configuration ofthe resource allocation to use for the corresponding UTC.

In one embodiment, the UE or WTRU may deactivate a UTC following thereception of a TAC that activates another UTC for the concerned channel,transmission type and/or serving cell or groups thereof. In someembodiments, this may be done if (or in some embodiments perhaps onlyif) a single UTC may be in the active state at any given time, amongother contemplated conditions.

Layer 3 signaling: The UE or WTRU may receive a configuration thatmodifies and/or remove one or more UTC(s) for one or more servingcell(s), upon which the concerned UTC may be deactivated (e.g. the UE orWTRU reverts to a default UTC of the concerned serving cell). The UE orWTRU may implicitly deactivate a UTC, and in one or more embodiments mayrevert to a default UTC, according to at least one of the following:

-   -   The time since the last transmission (or reception of control        signaling applicable to a transmission e.g. either scheduling on        PDCCH e.g. a grant and/or a DL HARQ feedback e.g. a HARQ        acknowledgement) that used the concerned UTC may be longer that        a specific value (possibly configured) (for example, a        tc-DeactivationTimer may be used for one or more, or each,        serving cell configured with a plurality of UTC(s);    -   The Timing Advance for the concerned UTC and/or serving cell may        be no longer valid e.g. the Timing Alignment Timer has expired;    -   The UE or WTRU receives control signaling that modifies the        configuration of the UTC for the concerned serving cell, in one        or more embodiments, if (or in some embodiments perhaps only if)        the UTC may not be the default UTC for the serving cell;    -   A HARQ process that may use a specific UTC has reached maximum        number of HARQ transmissions (e.g. a HARQ failure) (in one or        more embodiments, if the concerned UTC may be a default UTC, the        UE or WTRU may determine that the uplink experiences some form        of radio link failure e.g. UL RLF;    -   The UE or WTRU may determine that transmissions using the        concerned UTC may be experiencing radio link failure, e.g. upon        the UE or WTRU reaching the maximum number of preamble        transmissions, upon failure of DL timing and/or of DL PL        reference for the concerned UTC. In one or more embodiments, if        the concerned UTC may be a default UTC, the UE or WTRU may        determine that the uplink experiences some form of radio link        failure e.g. UL RLF; and/or    -   Implicit deactivation of one or more, or all, configured UTC(s)        for a given serving cell when the SCell may be deactivated.

When the UE or WTRU receives control signaling that deactivates one ormore UTC(s) for a given serving cell, the UE or WTRU may perform atleast one of the following: For a HARQ process for which a UTC may havebeen used, the UE or WTRU may consider the first assignment for thecorresponding HARQ buffer subsequent to the subframe in which theactivation state changes as a new (e.g., fresh or updated) transmission;The UE or WTRU may revert to the default UTC for other procedures suchas CQI reporting, SRS transmissions if applicable. Similar delay as forthe activation may be applied for the deactivation of a UTC. In oneembodiment, this may be done for a deactivation using explicitsignaling.

In order to determine connectivity for a UTC, the UE or WTRU may monitorthe radio link conditions of a radio link associated to a UTC, referredto hereafter as RLM for a UTC. The connectivity to a transmission pointmay be further determined according to the RACH procedure status. If theRACH procedures fail or if the timing alignment to a give UTC expires,the UE or WTRU may establish that the connectivity to a UTC has beenlost. In one or more embodiments, the UE or WTRU may determine thatconnectivity to a UTC does not exist if the difference in path lossbetween this UTC and a second UTC may be higher than a threshold.

The radio link monitoring of a UTC may be based on a downlink-specificreference signal that may be associated to the given UTC such as thePtRS. The reference signal may correspond to a CRS if such referencesignal exists for the given UTC or it may correspond to at least one ofthe reference signals configured as PtRS for the corresponding UTC.

For one or more, or each, determined UTC, as described below the UE orWTRU may monitor and estimate the downlink radio link quality andcompare it to the thresholds Qout and Qin. The thresholds associated toradio link monitoring (e.g. Qout/Qin, T310, N310) may be UTC specific orone common set of parameters may be configured and used to evaluateradio link failure in the UE or WTRU.

The UE or WTRU may determine for which UTCs to monitor radio linkquality or connectivity state according to at least one of thefollowing: monitoring for one or more, or all, configured UTCs may beperformed; monitoring for one or more, or all, active UTCs may beperformed; monitoring may be performed for at least one UTC configuredto be used for transmission of a specific subset of channels/signals.For instance, RLM may be performed for the UTC used to transmit a PUCCH.In another example the UTC for PUSCH may be monitored or that of theSRS. In yet another example, RLM may be performed for the UTC to be usedfor PUCCH/PUSCH transmissions; monitoring may be performed for aconfigured default UTC; monitoring may be performed on the best linkdetermined according to at least one of the following measurements:Channel quality (CQI) measurement, RSRP/RSRQ for the downlink channelassociated to the given UTC, or The UTC with largest PHR value (e.g., ifPHR may be determined for one or more, or all, configured/active UTCs));monitoring may be performed for a configured default UTC and another UTCdetermined according to any of the methods described above.

For one or more, or each, determined and selected UTC, RLM may beperformed on the associated downlink reference point. The quality of oneor more, or each, downlink signal may be independently monitored and thedetermination of a radio link failure on a specific link may beindependently determined and declared. When referred to hereafter aRadio Link Failure in a UTC may be referred to as one of the conditionsto determine that the connectivity to a UTC may be lost.

In an alternate embodiment the radio link monitoring/failuredetermination may be jointly performed for one or more, or all,monitored UTCs. More specifically, the physical layer downlink qualityof one or more, or all, sets may be independently monitored but the UEor WTRU may report (or in some embodiments may only report) anout-of-synch to higher layers if, among other contemplated conditions,the quality of one or more, or all, monitored sets may be below Qoutthreshold, otherwise an in-synch may be reported.

Upon determination of loss of connectivity (e.g. either RLF,out-of-synch, RACH failure, or a certain path loss differential may bedetected) in at least one UTC the UE or WTRU may perform one or acombination of the following actions: stop UL transmission to theassociated UTC; consider or set the activation state of the associatedUTC to deactivated; consider the TAT as expired for the UTC; remove theconfiguration of the UTC; or the UE or WTRU may stop transmitting thecorresponding channels using the failed UTC and may wait for an explicitorder or grant to start using a new (e.g., fresh or updated) UTC for theconfigured channel, where the UE or WTRU may start monitoring thedownlink of the default UTC or the sent in which it has fallen back asdescribed below.

The UE or WTRU may further choose to fall back to a different UTC forthe purpose of transmitting one or a subset of the transmission channelsor signal and/or for the purpose of downlink monitoring of the PDCCH andother configured downlink signals. The UTC to fall back on may bedetermined using at least one of the following: 1) The default UTC maybe chosen as a fallback UTC; or 2) The next available or activated UTCmay be determined to be the new (e.g., fresh or updated) UTC. If morethan one activated/configured sets may be available the UE or WTRU maychose: i) The UTC that provides the best downlink channel quality; ii)The first available UTC, wherein the order of UTC may be according tothe order in which they were configured in the RRC message or accordingto an explicit index provided in the configuration message; or iii) TheUTC in which another channels may be configured to perform transmissionsmay be chosen. For example, the UTC in which PUCCH may be transmittedmay be chosen as the next UTC to perform other UL transmissions.

In one or more embodiments, the new (e.g., fresh or updated) selectedUTC may be used by the UE or WTRU to establish a radio link connectionand communicate/transmit PUCCH or PUSCH to the eNB. The UE or WTRU mayperform one or a combination of the following actions on the new (e.g.,fresh or updated) selected UTC: 1) Start a preamble transmission usingthe transmission characteristics/parameters of the new (e.g., fresh orupdated) selected UTC; 2) Trigger a scheduling request on PUCCH usingselected set of transmission parameters and resources. In one or moreembodiments, the actions may be dependent on the UE or WTRU having avalid TAT or the UTC may be part of the same group as the failed UTC; or3) The UE or WTRU may indicate that RLF or that a loss of connectivityoccurred for at least one transmission point to the network by sending amessage to the network indicating at least one of, the reason for themessage (e.g. UTC failure), the failure reason (e.g. RLF, RACH, TATexpiry, etc), the failed UTC identity, UTC identity of the new (e.g.,fresh or updated) selected set. The message may transmitted via RRCsignaling, a MAC control element, or alternatively the UE or WTRU startsusing the new (e.g., fresh or updated) UTC characteristics. The changeof UTC characteristics or resource index may act as an implicitindication that the old UTC has failed and the UE or WTRU may be using anew (e.g., fresh or updated) UTC.

In one or more embodiments, if a default UTC fails, among othercontemplated conditions, the UE or WTRU may immediately declare RLFand/or may start the RRC re-establishment techniques, and in someembodiments may do so regardless of the connectivity status of the othernon-default UTCs.

In view of the description herein and the FIGS. 1-9, embodimentscontemplate one or more techniques and/or WTRU (or UE) configurationsthat may include obtaining characteristics derived from one of multipleUplink Transmission Contexts (UTC) and/or transmitting from a WTRU (orUE) based at least in part on the characteristics. In one or moreembodiments the characteristics may correspond to a certain intendedreception point. The intended reception point may operate on the samefrequency. In some embodiments the UTC may be characterized by at leastone Point Reference Signal. The contemplated techniques and/or WTRUconfigurations may be such that the UTC may be characterized by at leastone configuration parameter and/or state variable. In some embodiments,the characteristics may include a set of one or more parametersincluding, but not limited to, parameters of a WTRU's configurationincluding semi-static parameters configured by radio resource controller(RRC) including a maximum transmission power that may be used todetermine a transmission power for a transmission for a concerned UTC.

The contemplated techniques and/or WTRU configurations may be such thatthe characteristics may include a set of one or more propertiesincluding, but not limited to, properties derived from a WTRU'sconfiguration including a downlink (DL) path loss and/or timingreference derived from a grouping function, from a procedure performedby the UE such as a DL path loss estimate derived from a DL path lossreference used to determine a transmission power for a transmission fora concerned UTC.

The contemplated techniques and/or WTRU configurations may be such thatthe characteristics may include a set of one or more variables includingstate variables including an activated/deactivated UTC, and/or timersincluding a timer related to the validity of a timing advance value.

The contemplated techniques and/or WTRU configurations may be such thatthe characteristics may include one or more of: an uplink frequencyand/or a bandwidth for the said transmission; a transmission power toapply to the said transmission; a timing advance (or timing alignment)to apply to the said transmission; at least one property that may bespecific to the transmitted channel or signal, including (i) a propertyof at least one demodulation reference signal including cyclic shift,sequence group, antenna port, for physical uplink shared channel (PUSCH)or sounding reference signal (SRS) periodic or SRS aperiodic; (ii) atransmission format and/or resource; and/or (iii) a property of at leastone random access preamble.

Embodiments contemplate techniques and/or WTRU configurations forselecting Uplink Transmission Contexts for different types oftransmissions including physical uplink control channel (PUCCH), PUSCH,random access channel (RACH), sounding reference signal (SRS). Thecontemplated techniques and/or WTRU configurations may be such that theselecting may be based at least in part on an antenna port used totransmit downlink control signaling and/or the selecting based at leastin part on downlink measurements.

The contemplated techniques and/or WTRU configurations may includetriggering a power headroom report (PHR) when a path loss estimateapplicable to UTC may change by more than a threshold.

Embodiments contemplate techniques and/or WTRU configurations that mayinclude determining an activation state of a UTC; and/or detecting atrigger for at least one of an activation or de-activation. Thecontemplated techniques and/or WTRU configurations may such that thetrigger may be based on a received signal quality.

The contemplated techniques and/or WTRU configurations may includedetermining connectivity for a UTC based at least in part on one or moreof: (i) measurements on point reference signal, (ii) RACH proceduresuccess/failure and (iii) actions upon detection of loss of connectivitysuch as fallback to default UTC and/or a deactivation of UTC.

The contemplated techniques and/or WTRU configurations may includedetermining at least one characteristic of the following transmissioncharacteristics: an uplink frequency and/or a bandwidth for the saidtransmission; a transmission power to apply to the said transmission; atiming advance (or timing alignment) to apply to the said transmission;and/or at least one property that may be specific to the transmittedchannel or signal, such as: (i) a property of at least one demodulationreference signal (such as a cyclic shift, sequence group, antenna port);(ii) a transmission format and/or resource; and/or (iii) a property ofat least one random access preamble.

The contemplated techniques and/or WTRU configurations may includereceiving a Timing Advance Command (TAC) in a medium access channel(MAC) control element (CE) and/or in a random access response (RAR)message during the random access procedure; and/or determining to whatUTC the TAC applies. The contemplated techniques and/or WTRUconfigurations may be such that the UTC may be determined according toat least one of the following methods: (i) explicitly signaledidentifier in the message that contains the TAC (e.g. MAC TAC CE, RAR;(ii) explicitly signaled identifier in the control signaling thatschedules the message with the TAC; (iii) association between an uplinktransmission and the received TAC; and/or (iv) current activated UTC fora concerned serving cell or TA group.

The contemplated techniques and/or WTRU configurations may includetriggering and/or initiating a transmission of a power headroom report(PHR) at a WTRU according to at least one of the following: (i) the pathloss estimate for a given UTC changes by more than a threshold; and/or(ii) configuration, activation and/or change in activation state for agiven UTC. The contemplated techniques and/or WTRU configurations may besuch that the WTRU may trigger a power headroom (PHR) report when theactivation state of a UTC changes including either upon activation of aUTC and/or upon activation from explicit signaling received by the WTRUor upon activation that changes the state from deactivated to activated.

The contemplated techniques and/or WTRU configurations may be such thatthe PHR may include at least one of the following: (i) a PHR value forone or more, or all, configured UTC; (ii) a PHR value for one or more,or all, activated UTC; (iii) a PHR value for the selected UTC in thesubframe in which it performs an uplink transmission that may includeone or more PHR(s).

The contemplated techniques and/or WTRU configurations may includereceiving control signaling that may activate the use of carriersegments for one of more serving cells of the WTRU's configuration. Thecontemplated techniques and/or WTRU configurations may be such that thecontrol signaling may include at least one of the following: layer 1signaling; layer 2 signaling; layer 3 signaling; and/or a UE-autonomousactivation. The contemplated techniques and/or WTRU configurations maybe such that the Layer 1 signaling may include receiving a DCI format onphysical downlink control channel (PDCCH) that may indicate activationof a UTC for one or more serving cells.

The contemplated techniques and/or WTRU configurations may be such thatthe indication may be according to at least one of the following: theWTRU successfully decodes the DCI format using a configured radionetwork temporary identifier (RNTI) including a UTC-RNTI; the WTRU maydetermine that a DCI format may be of a certain type and/or includes anexplicit indication including a field and/or flag; and/or the WTRU mayreceive a DCI format that indicates a grant for an uplink transmission,a request for SRS transmission, or a TPC that may be applicable to aspecific UTC.

The contemplated techniques and/or WTRU configurations may also includetransmitting a hybrid automatic repeat request (HARM) acknowledgement(ACK) feedback to acknowledge the reception of the said DCI interpretedas the activation command. The contemplated techniques and/or WTRUconfigurations may be such that the Layer 2 signaling may includereceiving a MAC Control Element (CE) that may indicate activation of atleast one UTC for one or more serving cell(s) of the WTRU'sconfiguration.

The contemplated techniques and/or WTRU configurations may includechanging an activation state based on reception of a TAC at a UE. Thecontemplated techniques and/or WTRU configurations may includedetermining to what UTC the received TAC may be applicable, and/orchanging the activation state of the concerned TAC to “activated”. Thecontemplated techniques and/or WTRU configurations may also includedeactivating one or more other UTC of the concerned channel,transmission type and/or serving cell. The contemplated techniquesand/or WTRU configurations may be such that the Layer 3 signaling mayinclude receiving a configuration for one or more UTC (s), upon whichthe default UTC may be in the activated state. The contemplatedtechniques and/or WTRU configurations may be such that the UE-autonomousactivation includes measuring signal reception quality for a given UTC.

The contemplated techniques and/or WTRU configurations may includeconfiguring a WTRU with a plurality of UTC for a given serving cell;and/or performing an additional selection process to determine what UTCto use for an uplink transmission on the concerned serving cell. Thecontemplated techniques and/or WTRU configurations may includeselectively not using a UTC if the corresponding SCell may be in thedeactivated state.

The contemplated techniques and/or WTRU configurations may includereceiving control signaling at the WTRU that may deactivate the use ofone or more UTC for a given serving cell of the WTRU's configuration.The contemplated techniques and/or WTRU configurations may be such thatthe control signaling may include at least one of the following: layer 1signaling; layer 2 signaling; and/or layer 3 signaling.

The contemplated techniques and/or WTRU configurations may includereceiving control signaling that may deactivate one or more UTC(s) for agiven serving cell; performing at least one of the following: for a HARQprocess for which a UTC may have been used, the WTRU may consider thefirst assignment for the corresponding HARQ buffer subsequent to the subframe in which the activation state may change as a new (e.g., fresh orupdated) transmission; and/or the WTRU may revert to the default UTC forother procedures such as channel quality indicator (CQI) reporting, SRStransmissions if applicable.

The contemplated techniques and/or WTRU configurations may includedetermining connectivity for a UTC by, at a WTRU monitoring the radiolink conditions of a radio link associated to a UTC or according to theRACH procedure status, and/or according to a determined difference inpath loss between this UTC and a second UTC may be higher than athreshold. The contemplated techniques and/or WTRU configurations may besuch that the radio link monitoring of a UTC may be based at least inpart on a downlink-specific reference signal that may be associated tothe given UTC, such as the Point Reference Signal (PtRS). Thecontemplated techniques and/or WTRU configurations may be such that forone or more, or each, determined UTC, the WTRU may monitor and estimatethe downlink radio link quality and/or compare it to thresholds Qout andQin.

The contemplated techniques and/or WTRU configurations may includedetermining a loss of connectivity including a radio link failure (RLF),out-of-synch, RACH failure, or a certain path loss differential may bedetected) in at least one UTC; performing one or a combination of thefollowing actions stop UL transmission to the associated UTC; consideror set the activation state of the associated UTC to deactivated;consider the TAT as expired for the UTC; remove the configuration of theUTC; and/or the WTRU stops transmitting the corresponding channels usingthe failed UTC and waits for an explicit order or grant to start using anew (e.g., fresh or updated) UTC for the configured channel.

The contemplated techniques and/or WTRU configurations may includedetermining a UTC to fall back on using at least one of the following:choosing the default UTC; and/or choosing the next available oractivated UTC. The contemplated techniques and/or WTRU configurationsmay be such that if more than one activated/configured sets may beavailable, the WTRU may choose one or more of: (i) the UTC that providesthe best downlink channel quality, (ii) the first available UTC, whereinthe order of UTC may be according to the order in which they wereconfigured in the RRC message or according to an explicit index providedin the configuration message; and/or (iii) the UTC in which anotherchannel may be configured to perform transmissions. The contemplatedtechniques and/or WTRU configurations may include using the new (e.g.,fresh or updated) selected UTC by the WTRU to establish a radio linkconnection and communicate/transmit PUCCH or PUSCH to the eNB. Thecontemplated techniques and/or WTRU configurations may be such that theWTRU may perform one or more of the following actions on a new (e.g.,fresh or updated) selected UTC:

starting a preamble transmission using the transmissioncharacteristics/parameters of the new (e.g., fresh or updated) selectedUTC; triggering a scheduling request on PUCCH using selected set oftransmission parameters and resources; and/or indicating that RLF orthat a loss of connectivity occurred for at least one transmission pointto the network by sending a message to the network indicating at leastone of, the reason for the message, the failure reason, the failed UTCidentity, and/or UTC identity of the new (e.g., fresh or updated)selected set.

The contemplated techniques and/or WTRU configurations may includecontrolling power by one or more of the following: controlling the powerof SRS in the absence of a PUSCH transmission; and/or controlling thepower of a RACH preamble where a UTC may have a multiple point referencesignals.

The contemplated techniques and/or WTRU configurations may includepre-compensating a correlation drift peak by applying a pre-compensationoffset value on top of a planned cyclic shift setting when multiple UEsmay be co-scheduled for uplink transmission. The contemplated techniquesand/or WTRU configurations may be such that the pre-compensation offsetvalue may be calculated in the reverse direction of the correlation peakdrift. The contemplated techniques and/or WTRU configurations may besuch that the WTRU may autonomously perform the CS compensation withoutinvolvement of the network operation. The contemplated techniques and/orWTRU configurations may be such that the additional dynamic signalingmechanism may be introduced to inform the WTRU of the pre-compensationoffset value used by the other WTRUs under co-scheduling.

The contemplated techniques and/or WTRU configurations may be such thatthe pre-compensation offset value may be signaled as part of an uplinktransmission context corresponding to properties of a certain potentialdestination point that may allow the network to indicate one of multiplepre-compensation offset values from an indicated uplink transmissioncontext. The contemplated techniques and/or WTRU configurations may besuch that the network may apply the pre-compensation offset value. Thecontemplated techniques and/or WTRU configurations may also includeadding another layer of hopping that may be reference signal RS lengthdependent. The contemplated techniques and/or WTRU configurations may besuch that the RS length dependent hopping may be combined into a grouphopping pattern. The contemplated techniques and/or WTRU configurationsmay be such that the initial value for CS hopping may be decoupled andstill cell-specific.

The contemplated techniques and/or WTRU configurations may be such thatthe CS hopping may be independently configured via higher layersignaling with a WTRU-specific adjustment. The contemplated techniquesand/or WTRU configurations may be such that the WTRU-specific adjustmentmay be dynamically assigned in the most recent uplink-related downlinkcontrol information (DCI). The contemplated techniques and/or WTRUconfigurations may be such that the additional randomization may beperformed over demodulation reference signal (DMRS) of differentlengths. The contemplated techniques and/or WTRU configurations mayinclude determining an initial value for cyclic shift hopping based onreinterpretation of cyclic shift field.

The contemplated techniques and/or WTRU configurations may include usingdifferent transmit power control (TPC) commands for aperiodic soundingreference signal (ASRS), periodic SRS (PSRS), and/or physical uplinkshared channel (PUSCH). The contemplated techniques and/or WTRUconfigurations may be such that the PUSCH resource blocks (RBs) may bemodified in view of dynamic PUSCH RB allocation. The contemplatedtechniques and/or WTRU configurations may be such that the one or more,or each, physical channel may have a TPC command chain.

The contemplated techniques and/or WTRU configurations may be such thatthe multiple TPC command chains may be used for one or more, or one ormore, or each, configured physical channel. The contemplated techniquesand/or WTRU configurations may be such that different UTC may share asubset of parameters for different SRS. The contemplated techniquesand/or WTRU configurations may be such that some parameters linked to aphysical channel or transmission type used by a UTC may be configured ortransmitted by another UTC. The contemplated techniques and/or WTRUconfigurations may be such that an indication of UTC for which aconfiguration or parameter may apply may be in the transmission of theconfiguration or parameter. The contemplated techniques and/or WTRUconfigurations may be such that the ASRS, PSRS and/or PUSCH may maintaina TPC command chain. The contemplated techniques and/or WTRUconfigurations may be such that an ASRS trigger may include aninformation element which provides a TPC command.

The contemplated techniques and/or WTRU configurations may be such thatthe TPC command may be used for at least one of ASRS, PSRS, and/orPUSCH. The contemplated techniques and/or WTRU configurations may besuch that a bitfield may be used to indicate which point the TPC commandmay be for. The contemplated techniques and/or WTRU configurations maybe such that the bitfield may use a preconfigured mapping. Thecontemplated techniques and/or WTRU configurations may be such that aSRS Request Field may be used to indicate for what transmission type theTPC command may be to be used for. The contemplated techniques and/orWTRU configurations may be such that a PUSCH TPC command may include abitfield which may indicate for which combination of transmission typesa TPC command may be for. The contemplated techniques and/or WTRUconfigurations may be such that a DCI may be used to indicate TPCcommands.

The contemplated techniques and/or WTRU configurations may be such thata linkage between different periods/offsets of the DCI and TPC commandfor different transmission types may be preconfigured at the WTRU. Thecontemplated techniques and/or WTRU configurations may be such that themultiple SRS for multiple UTC may serve different purposes. Thecontemplated techniques and/or WTRU configurations may be such that afrequency for which one or more, or one or more, or each, SRS istransmitted may be different. The contemplated techniques and/or WTRUconfigurations may be such that a linkage may exist between thefrequency that TPC commands may be sent for an SRS and the frequencywith which this SRS may be transmitted by the WTRU.

The contemplated techniques and/or WTRU configurations may be such thatone or more, or one or more, or each, type of SRS or PUSCH may bepreconfigured with a specific mapping of TPC command field value andcorrection value. The contemplated techniques and/or WTRU configurationsmay be such that the parameters used for the determination of the RBsused for PUSCH may be set to a first set of values in a first UTC and toa second set of values in a second UTC. The contemplated techniquesand/or WTRU configurations may be such that an UTC, or at least oneparameter associated with the UTC, may be determined based on a lowestcontrol channel elements (CCE) index used to construct a physicaldownlink control channel (PDCCH) used for transmission of acorresponding downlink control indicator (DCI) assignment.

The contemplated techniques and/or WTRU configurations may be such thatat least one of power settings parameters, TPC commands and/or SRS powercontrol adjustment states for aperiodic SRS (ASRS) may correspond to thepower settings parameters, TPC commands and/or SRS power controladjustment states of physical uplink control channel (PUCCH).

The contemplated techniques and/or WTRU configurations may be such thata power control adjustment state for SRS may be modified by reception ofa TPC command in a downlink assignment. The contemplated techniquesand/or WTRU configurations may be such that a value of an offset may bea function of a value of a SRS request field. The contemplatedtechniques and/or WTRU configurations may be such that a TPC command maybe kept separate between the ASRS, periodic SRS (PSRS) and/or PUSCH, andon a value of the SRS request field used to trigger ASRS. Thecontemplated techniques and/or WTRU configurations may be such that aTPC field may be reinterpreted to indicate both a power controladjustment and an indication of whether the power control adjustmentapplies to at least one of ASRS, PSRS and/or PUSCH.

The contemplated techniques and/or WTRU configurations may be such thatthe TPC command may apply to PUSCH on a condition that the TPC commandmay be received as part of downlink control information (DCI) that mayinclude an uplink grant, wherein a SRS request field indicates that ASRSmay not be triggered. The contemplated techniques and/or WTRUconfigurations may be such that the TPC command may apply to ASRS on acondition that the TPC command may be received as part of a DCI that mayinclude an uplink grant, wherein a SRS request field indicates that ASRSmay be triggered. The contemplated techniques and/or WTRU configurationsmay be such that the TPC command may apply to PUSCH on a condition thatthe TPC command may be received as part of downlink control information(DCI) that may include an uplink grant, wherein a SRS request field mayindicate that ASRS may not be triggered. The contemplated techniquesand/or WTRU configurations may be such that the ASRS may be triggeredwith different values of the SRS request field that may maintainseparate power control adjustment states.

The contemplated techniques and/or WTRU configurations may be such thata TPC command received as part of a DCI containing an uplink grant mayapply to the ASRS triggered with the value of the SRS request field inthe same DCI. The contemplated techniques and/or WTRU configurations maybe such that the TPC command may apply to ASRS on a condition that theDCI may be such that the transmission of a transport block (in uplink)may be disabled. The contemplated techniques and/or WTRU configurationsmay be such that the applicability of the TPC command may depend on theDCI format in which it may be received. The contemplated techniquesand/or WTRU configurations may be such that a TPC command received inDCI format 3 may apply to one or more of PUSCH, ASRS, and/or PSRS. Thecontemplated techniques and/or WTRU configurations may be such that aTPC command received in DCI format 4 may apply to ASRS.

The contemplated techniques and/or WTRU configurations may be such thatthe applicability of the TPC command may depend on the value of a radionetwork temporary identifier used to mask a cyclic redundancy check(CRC) of the DCI. The contemplated techniques and/or WTRU configurationsmay be such that on a condition that a CRC may be used in the encodingof the DCI for an uplink grant may be masked with a first RNTI, the UTCfor the PUSCH transmission and associated DM-RS may correspond to afirst UTC.

The contemplated techniques and/or WTRU configurations may be such thaton a condition that a CRC used in the encoding of the DCI may be maskedwith a second RNTI, the UTC for the PUSCH transmission and associatedDM-RS may correspond to a second UTC. The contemplated techniques and/orWTRU configurations may be such that the UTC used for a PUCCHtransmission may be selected based on a physical resource block (PRB) inwhich the PUCCH transmission takes place. The contemplated techniquesand/or WTRU configurations may be such that the UTC used for a PUCCHtransmission may be set to a first UTC on a condition that the PRBbelongs to a first set of PRB's, and to a second UTC on a condition thatthe PRB belongs to a second set of PRB's. The contemplated techniquesand/or WTRU configurations may be such that the at least one of thephysical cell identity, and power control parameters and variables maybe selected based on the PRB used for the PUCCH.

The contemplated techniques and/or WTRU configurations may be such thatthe UTC used for a PUCCH transmission may be selected based on aspecific set of uplink transmission properties of PUCCH as indicated bya PUCCH resource index for a certain PUCCH format. The contemplatedtechniques and/or WTRU configurations may be such that the UTC used fora PUCCH transmission may be set to a first UTC on a condition that aresource index may be within a first range (or set) of values, and to asecond UTC on a condition that the resource index may be within a secondrange (or set) of values. The contemplated techniques and/or WTRUconfigurations may be such that a power control parameter may be tied toa subframe.

The contemplated techniques and/or WTRU configurations may be such thatone or more, or one or more, or each, of periodic SRS and multipleaperiodic SRS may be configured with different UTCs. The contemplatedtechniques and/or WTRU configurations may be such that the different TPCcommand loops may be maintained for one or more, or one or more, oreach, of PSRS, multiple ASRS, PUSCH and/or PUCCH. The contemplatedtechniques and/or WTRU configurations may be such that the combinationsof SRS types and PUSCH and PUCCH may use the same TPC command values inpower control formulas. The contemplated techniques and/or WTRUconfigurations may be such that the TPC commands may be applied to agroup of UTC may be cumulative.

The contemplated techniques and/or WTRU configurations may be such thatthe TPC commands used for single UTC may be valid for one instance of ULtransmission on the UTC. The contemplated techniques and/or WTRUconfigurations may be such that the groups of physical channels ortransmission types may be updated with the same TPC command. Thecontemplated techniques and/or WTRU configurations may be such that theWTRU may maintain separate power control adjustment states for one ormore, or one or more, or each, group. The contemplated techniques and/orWTRU configurations may be such that a power control loop for which aTPC command may be intended may depend on a subframe number within whichthe TPC command is transmitted.

The contemplated techniques and/or WTRU configurations may be such thata subgroup of physical channels and/or transmission types may bepreconfigured to be tied to a subset of subframes. The contemplatedtechniques and/or WTRU configurations may be such that on a conditionthat a group of physical channels and/or transmission types share a TPCcommand, one or more, or one or more, or each, individual physicalchannel and/or transmission type may be configured to apply a differentoffset to an over-all TPC command chain. The contemplated techniquesand/or WTRU configurations may be such that when a group of physicalchannels and/or transmission types share a TPC command, one or more, orone or more, or each, individual physical channel and/or transmissiontype may interpret a TPC command codepoint differently. The contemplatedtechniques and/or WTRU configurations may be such that a choice of UTCmay depend on a subframe number.

The contemplated techniques and/or WTRU configurations may be such thata subset of subframes may be determined from at least one of framenumber, subframe number, offset and/or periodicity. The contemplatedtechniques and/or WTRU configurations may be such that a TPC command maybe applicable for physical channels or transmission types whose UTCs maybe used in the subframe in which the TPC command was transmitted. Thecontemplated techniques and/or WTRU configurations may be such that on acondition that a TPC command is transmitted in a subframe subset, UTCsand/or physical channels and/or transmission types configured to be usedfor that subset of subframes may use the TPC command. The contemplatedtechniques and/or WTRU configurations may be such that a TPC command maybe tied to a specific physical channel and/or transmission type,independent of the UTC. The contemplated techniques and/or WTRUconfigurations may be such that TPC commands transmitted in DCI Format 3may be used for one or more, or all, subframes and any other TPC commandmay be valid for a subset of subframes.

The contemplated techniques and/or WTRU configurations may be such thatthe a network may configure the UE with a subset of subframes for whichit may use regular uplink transmission and another subset of subframesfor which it may use limited transmission. The contemplated techniquesand/or WTRU configurations may be such that a WTRU may be configuredwith one set of UTCs, one or more, or one or more, or each, configuredwith a specific transmission power offset. The contemplated techniquesand/or WTRU configurations may be such that in another subset ofsubframes, the WTRU may be configured with another set of UTCs which maybe near a replica of a first set of UTCs except for differences in sometransmission parameters.

The contemplated techniques and/or WTRU configurations may be such thata WTRU may be configured with subsets of subframes where for differentsubsets it may use different UTCs. The contemplated techniques and/orWTRU configurations may be such that for one or more, or each, subset ofsubframes and one or more, or each, UTC, a different PCMAX,c may beconfigured. The contemplated techniques and/or WTRU configurations maybe such that a WTRU may maintain separate HARQ processes based on asubframe subset of an original transmission. The contemplated techniquesand/or WTRU configurations may be such that a WTRU may be configuredwith multiple subframe subsets.

The contemplated techniques and/or WTRU configurations may be such thatfor one or more, or each, subframe subset, the WTRU may use differenttransmission powers. The contemplated techniques and/or WTRUconfigurations may be such that different subframe subsets may beconfigured with different PCMAX,c. The contemplated techniques and/orWTRU configurations may be such that a WTRU may be configured withdifferent UTCs for one or more, or each, of the subframe subsets. Thecontemplated techniques and/or WTRU configurations may be such that forone or more, or each, UTC, the WTRU may report PHR based on UTC-specificpower control parameters. The contemplated techniques and/or WTRUconfigurations may be such that a same UTC may be used for a specificphysical channel and/or transmission type over one or more, or all,different subframe subsets.

The contemplated techniques and/or WTRU configurations may be such thata WTRY may have multiple power control parameters for one or more, oreach, UTC, where one or more, or each, subframe subset may have apre-configured set of power control parameters. The contemplatedtechniques and/or WTRU configurations may be such that a WTRU may reportmultiple power headroom report (PHR) values for one or more, or each,UTC. The contemplated techniques and/or WTRU configurations may be suchthat one or more, or each, PHR value may correspond to a subframesubset. The contemplated techniques and/or WTRU configurations may besuch that a WTRU may include a subframe subset identifier in the PHR.The contemplated techniques and/or WTRU configurations may be such thata PHR report may be valid for a subset of subframes within which it maybe transmitted.

Although features and elements are described above in particularcombinations, one of ordinary skill in the art will appreciate that eachfeature or element can be used alone or in any combination with theother features and elements. In addition, the methods described hereinmay be implemented in a computer program, software, or firmwareincorporated in a computer-readable medium for execution by a computeror processor. Examples of computer-readable media include electronicsignals (transmitted over wired or wireless connections) andcomputer-readable storage media. Examples of computer-readable storagemedia include, but are not limited to, a read only memory (ROM), arandom access memory (RAM), a register, cache memory, semiconductormemory devices, magnetic media such as internal hard disks and removabledisks, magneto-optical media, and optical media such as CD-ROM disks,and digital versatile disks (DVDs). A processor in association withsoftware may be used to implement a radio frequency transceiver for usein a WTRU, UE, terminal, base station, RNC, or any host computer.

What is claimed is:
 1. A wireless transmit/receive unit (WTRU),comprising: a receiver configured to receive downlink controlinformation (DCI) and a configuration having at least two sets of powercontrol parameters, each set of power control parameters having at leastinformation of a desired received power and a partial path-losscompensation; a processor configured, at least in part, to: select a setof power control parameters, based on the DCI, from the at least twosets of power control parameters for an uplink transmission; anddetermine a desired received power and a partial path-loss compensationassociated with the uplink transmission based on the set of powercontrol parameters and the DCI; derive a path-loss estimate from a setof path-loss references based on the DCI; and identify a power controladjustment state associated with the uplink transmission based on theDCI; and a transmitter configured to transmit the uplink transmissionusing a power based on at least the desired received power, the partialpath-loss compensation, the path-loss estimate, and the power controladjustment state.
 2. The WTRU of claim 1, wherein the DCI includes atleast an index associated with the set of power control parameters. 3.The WTRU of claim 1, wherein the uplink transmission is transmitted viaa Physical Uplink Shared Channel (PUSCH).
 4. A method performed by awireless transmit/receive unit (WTRU), the method comprising: receivingdownlink control information (DCI) and a configuration having at leasttwo sets of power control parameters, each set of power controlparameters having at least information of a desired received power and apartial path-loss compensation; selecting a set of power controlparameters, based on the DCI, from the at least two sets of powercontrol parameters for an uplink transmission; determining a desiredreceived power and a partial path-loss compensation associated with theuplink transmission, based on the set of power control parameters andthe DCI; maintaining a set of power control adjustment states;selecting, from the set of power control adjustment states, a powercontrol adjustment state associated with the uplink transmission basedon the DCI; and transmitting the uplink transmission using a power basedon at least the desired received power, the partial path-losscompensation, and the power control adjustment state.
 5. The method ofclaim 4, wherein the DCI includes at least an index associated with theset of power control parameters.
 6. The method of claim 4, wherein theuplink transmission is transmitted via a Physical Uplink Shared Channel(PUSCH).
 7. The WTRU of claim 1, wherein the DCI is associated with oneor more Transmit Power Control (TPC) commands.
 8. The WTRU of claim 1,wherein when identifying the power control adjustment state, theprocessor is configured to maintain a TPC command chain.
 9. The WTRU ofclaim 1, wherein the configuration is a Radio Resource Control (RRC)configuration, and the at least two sets of power control parameters areconfigured by the RRC configuration.
 10. The WTRU of claim 1, whereinthe DCI includes a DCI format.
 11. The WTRU of claim 1, wherein theprocessor is configured to determine a maximum transmit power percarrier associated with the uplink transmission.
 12. The method of claim4, wherein the DCI is associated with one or more TPC commands.
 13. Themethod of claim 4, wherein maintaining the set of power controladjustment states comprises maintaining a TPC command chain.
 14. Themethod of claim 4, wherein the configuration is a Radio Resource Control(RRC) configuration, and the at least two sets of power controlparameters are configured by the RRC configuration.
 15. The method ofclaim 4, wherein the DCI includes a DCI format.
 16. The method of claim4, further comprising determining a maximum transmit power per carrierassociated with the uplink transmission.
 17. The WTRU of claim 1,wherein the processor is configured to: maintain a set of power controladjustment states, and select the power control adjustment state fromthe set of power control adjustment states.
 18. The method of claim 4,further comprising: deriving a path-loss estimate from a set ofpath-loss references based on the DCI, and wherein the power used fortransmitting the uplink transmission is further based on the path-lossestimate.
 19. A wireless transmit/receive unit (WTRU), comprising: areceiver configured to receive downlink control information (DCI) and aconfiguration having at least two sets of power control parameters, eachset of power control parameters having at least information of a desiredreceived power and a partial path-loss compensation; a processorconfigured, at least in part, to: select a set of power controlparameters, based on the DCI, from the at least two sets of powercontrol parameters for an uplink transmission; and determine a desiredreceived power[and a partial path-loss compensation associated with theuplink transmission based on the set of power control parameters and theDCI; maintain a set of power control adjustment states; and select, fromthe set of power control adjustment states, a power control adjustmentstate associated with the uplink transmission based on the DCI; and atransmitter configured to transmit the uplink transmission using a powerbased on at least the desired received power, the partial path-losscompensation, and the power control adjustment state.
 20. The WTRU ofclaim 19, wherein the processor is configured to: derive a path-lossestimate from a set of path-loss references based on the DCI, andwherein the power used by the transmitter for transmitting the uplinktransmission is further based on the path-loss estimate.